Citrus tristeza virus based vectors for foreign gene/S expression

ABSTRACT

Disclosed herein are viral vectors based on modifications of the Citrus Tristeza virus useful for transfecting citrus trees for beneficial purposes. Included in the disclosure are viral vectors including one or more gene cassettes that encode heterologous polypeptides. The gene cassettes are positioned at desirable locations on the viral genome so as to enable expression while preserving functionality of the virus. Also disclosed are methods of transfecting plants and plants transfected with viral vector embodiments.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is related to U.S. Provisional Application No. 61/537,154 filed Sep. 21, 2011, to which priority is claimed under 35 USC 119 and which is incorporated herein by reference and is a continuation-in-part of U.S. Ser. No. 12/174,159 filed Jul. 16, 2008 which issued is U.S. Pat. No. 8,629,334 on Jan. 14, 2014.

SEQUENCE LISTING

The instant application contains a Sequence Listing which has been submitted in ASCII format via EFS-Web and is hereby incorporated by reference in its entirety. Said ASCII copy, created on Dec. 27, 2012, is named 10457204.txt and is 18,121 bytes in size.

BACKGROUND

The early development of viral vectors was aimed at the inexpensive production of high levels of specialty proteins that could be scaled up in the field. The first attempt at a plant viral vector utilized Cauliflower mosaic virus, a dsDNA virus (Brisson et al., 1984; Gronenborn et al., 1981). However, this vector was too unstable to be useful (Fütterer et al., 1990). The development of reverse genetics systems amenable for manipulation of RNA viruses made many more viruses candidates for vector development (Ahlquist et al., 1984).

Virus vectors are key ingredients in basic research and have great potential for commercial applications. Lack of stability of foreign inserts has been a major drawback for potential applications of virus vectors for commercial protein expression in field applications.

SUMMARY

The present disclosure is based on multiple studies testing the vector limits of using CTV to express foreign genes ranging from 806 to 3480 nucleotides in size. In one embodiment, gene cassettes were introduced into the CTV genome as replacement of the p13 gene. In other embodiments, a gene was inserted at different locations (e.g., p13-p20, p20-p23 and p23-3′NTR (non-translated region)). In another embodiment, a fusion to p23 and protease processing were tested. In alternative embodiments, genes were inserted behind IRES sequences to create bi-cistronic messages.

Twenty seven expression vectors have been created and tested in Nicotinia benthamiana protoplasts and plants. Remarkably, most of the newly developed vector constructs disclosed herein replicated, spread systemically in plants, and produced their foreign gene(s). The highest expressing vectors tested include the “add a gene” constructs having an insertion between the p13 and p20 genes or between the p23 gene and the 3′NTR. Similarly, the vectors with the inserted gene replacing the p13 gene effectively expressed different reporter genes. However, optimal expression of the reporter gene depended both on the size and location of the insertion. Optimal expression of smaller genes are from positions nearer the 3′ terminus, whereas larger genes are optimally expressed from more internal positions.

Efficient expression of two genes simultaneously from the same vector has been accomplished in both N. benthamiana and citrus. The novel CTV constructs disclosed herein have genomes with unique elasticity capable of accommodating and expressing foreign gene/s by different strategies.

Engineering an effective vector requires a balance between different factors. The vector needs to be designed such that replication and systemic movement in the plant are reduced minimally while the level of expression of the foreign protein is maximal (Shivprasad et al., 1999). The final factor is the stability of the vector. In general, the vector's usefulness is directly correlated with its stability. Stability is a product of reduced recombination and increased competitiveness of the vector with the resulting recombinants that have lost part or all of the inserted sequences.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1. GFP replacement of p13 to produce CTV based expression vectors. (A) Schematic representation of CTV9RΔp33 (Boxes represent open reading frames with blue outline of boxes represent the replication gene block whereas the red outline represent the closterovirus conserved gene block (Karasev, 2000). The black circle and black boxes outline represent silencing suppressors (Lu et al., 2004). Gold box outline represent genes dispensible for the infection of some citrus genotypes (Tatineni et al., 2008). Filled black rectangle represents the deletion of the p33 controller elements and ORF (nts 10858-11660 Genebank Accession # AY170468) (Satyanarayana et al., 1999; 2000; 2003)). Arrows indicate the processing of the leader proteases of CTV, LP1 and LP2 are two tandem leader protease, MT (methyl transferase), Hel (Helicase), RdRp (RNA dependent RNA polymerase, 433 (deletion of the 33 kda protein sequence), p6 (6 kda protein), Hsp70h (heat shock protein 70 homologue), p61 (61 kda protein), CPm (minor coat protein), CP (major coat protein, inter cellular silencing suppressor), p18 (18 kda protein), p13 (13 kda protein), p20 (20 kda protein, inter/intra cellular silencing suppressor), p23 (23 kda protein, intracellular silencing suppressor) and modification to produce expression vectors CTV33-Δ13-BY-GFP-57 (C57), CTV33-Δ13-G-GFP-65 (C65), CTV33-Δ13-B-GFP-66 (C66) with the CP-CE of BYSV, GLRaV-2 and BYV driving GFP, respectively. (B) Northern blot analysis of wild type CTV (WT) and CTV based expression vector transfected to N. benthamiana protoplast (T) and passaged to a new set of protoplasts (P). (C) Representative sample of fluorescence in N. benthamiana infected with either of the three constructs CTV33-Δ13-BY-GFP-57, CTV33-Δ13-G-GFP-65, CTV33-Δ13-B-GFP-66 magnified under a fluorescent stereoscope. (D) Representative sample of fluorescence in the phloem of citrus bark pieces infected with constructs CTV33-Δ13-G-GFP-65 and CTV33-Δ13-B-GFP-66 with high (left) and low (right) magnification under a fluorescent stereoscope.

FIG. 2 GUS replacement of p13 to produce CTV based expression vectors. (A) Schematic representation of CTV9RΔp33 and its modification creating expression vector CTV33-Δ13-BY-GUS-61 in which the p13 and its controller element is replaced by GUS under the control of CP-CE of BYSV. (B) Northern blot hybridization analysis of wild type CTV (WT) and CTV based expression vector CTV33-Δ13-BY-GUS-61 (C61) transfected to N. benthamiana protoplast (T) and passaged to a new set of protoplasts (P). (C) Representative sample of GUS activity in the bark pieces of citrus trees infected with construct CTV33-Δ13-BY-GUS-61 (right) and the GUS solution before fixing of the bark pieces (left) (A=Healthy control, B=infect).

FIG. 3 GFP insertion between p13 and p20 to produce CTV based expression vectors. (A) Schematic representation of CTV9RΔp33 and modification by inserting between p13 and p20 of GFP ORF under the control of BYSV creating expression vector CTV33-13-BY-GFP-69 (B) Northern blot hybridization analysis of transfected protoplast with the wild type virus (WT) and expression vector CTV33-13-BY-GFP-69 (C69) from transcripts (T) and their passages (P). Representative sample of fluorescence in N. benthamiana (C) and peeled bark phloem pieces of C. macrophylla (D) infected with CTV33-13-BY-GFP-69 magnified under a fluorescent stereoscope.

FIG. 4 GFP insertion between p20 and p23 to produce CTV based expression vectors. (A) Schematic representation of CTV9RΔp33 and its modification producing expression vector CTV33-20-B-GFP-49 and CTV33-20-BY-GFP-58, respectively. (B) Northern blot hybridization analysis of transfected protoplast with the wild type virus (WT) and expression vectors CTV33-20-B-GFP-49 (C49) and CTV33-20-BY-GFP-58 (C58) from transcripts (T) and their passages (P). (C) Flourescence under UV light of protoplast (right) and the leaf (left) showing lack of efficient movement of the vector. (D) Western blot analysis of the same gene inserted at different locations in the CTV genome. BCN5 (Folimonov et al., 2007) original CTV vector (contains GFP under BYV promoter between CPm and CP), constructs CTV33-23-BY-GFP-37 (C37, insertion of BYSV driving GFP behind p23), CTV33-20-BY-GFP-58 (C58, insertion of BYSV driving GFP between p20 and p23), CTV33-13-BY-GFP-69 (C69, insertion of BYSV driving GFP between p13 and p20), CTV33-Δ13-BY-GFP-57 (C57, replacement of p13 gene with BYSV CP-CE driving GFP) and CTV33-27-BY-GFP-63 (C63, Insertion of BYSV CP-CE driving GFP ORF between CPm and CP).

FIG. 5 GFP insertion between p23 and 3′NTR to produce CTV based expression vectors. (A) Schematic representation of CTV9RΔp33 and its modification by insertion of GFP behind p23 under control of CP-CE of BYSV, GLRaV-2 and BYV creating expression CTV33-23-BY-GFP-37 (C37), CTV33-23-G-GFP-40 (C40) and CTV33-23-B-GFP-42 (C42), respectively. (B) Northern blot hybridization analysis of transfected protoplast with the wild type virus (WT) and expression vectors CTV33-23-BY-GFP-37, CTV33-23-G-GFP-40 and CTV33-23-B-GFP-42 from transcripts (T) and their passages (P). (C) Representative sample of fluorescence in N. benthamiana infected with either of the three constructs CTV33-23-BY-GFP-37, CTV33-23-G-GFP-40 and CTV33-23-B-GFP-42 magnified under a fluorescent stereoscope. (D) Representative sample of fluorescence in the phloem tissue of Citrus macropylla infected with constructs CTV33-23-BY-GFP-37 and CTV33-23-G-GFP-40.

FIG. 6 GUS insertion between p23 and 3′NTR insertion between p23 and 3′NTR to produce CTV based expression vectors. (A) Schematic representation of CTV9RΔp33 and modification by insertion of GUS ORF under control of BYSV CP-CE between p23 and 3′NTR creating expression vector CTV33-23-BY-GUS-60 (C60). (B) Northern blot hybridization analysis of transfected protoplast with the wild type virus (WT) and expression vectors CTV33-23-BY-GUS-60 from transcripts (T). (C) Enzymatic activity of the GUS protein in N. benthamiana tissue and citrus phloem bark pieces (Blue color indicate infected plant and colorless tissue and solution indicate healthy control and GUS solution subject to the same treatment.

FIG. 7 GFP inserted behind IRES sequences to create CTV based expression vectors. (A) Schematic representation of CTV9RΔp33 and CTVΔCla 333R and their modification behind p23 creating expression vectors CTV33-23-ITEV-GFP-41; CTV33-23-I3×ARC-GFP-43 represent the TEV 5′NTR IRES and 3×ARC-1 IRES, respectively and CTVp333R-23-ITEV-GFP; CTVp333R-23-I3×ARC-GFP representing the TEV 5′NTR IRES and 3×ARC-1 IRES, respectively. (B) 1—Northern blot hybridization analysis from tranfected N. benthamiana protoplast with wild type virus (WT), CTV33-23-ITEV-GFP-41 (C41) and CTV33-23-I3×ARC-GFP-43 (C43); T=RNA isolated from transcript transfected protoplast and P=RNA isolated from virion transfected protoplast isolated from RNA transfected protoplast. 2-Northern blot hybridization analysis from protoplast transfected with CTVp333R-23-ITEV-GFP (Lane A); CTVp333R-23-I3×ARC-GFP (lane B), CTVp333R (lane C) and CTVp333R-23-B-GFP (BYV CP-CE driving the expression of GFP behind p23) (Lane D).

FIG. 8 GFP and a protease fused to p23 to create CTV based expression vectors. (A) Schematic representation of CTV9RΔp33 and the modifications by fusing two TEV proteases (NIa and HC-Pro) and their recognition sequences to create expression vectors CTV33-23-HC-GFP-72, CTV33-23-NIa-GFP-73, CTV33-23-HCØ-GFP-74 and CTV33-23-NIaØ-GFP-75.

FIG. 9 Comparison of Florescence in N. benthamiana. (A) Comparison of fluoresce in infiltrated leaves of representative samples of constructs CTV33-23-HC-GFP-72, CTV33-23-NIa-GFP-73, CTV33-23-HCØ-GFP-74 and CTV33-23-NIaØ-GFP-75 (GFP fused) and CTV33-23-BY-GFP-37, CTV33-23-G-GFP-40 and CTV33-23-B-GFP-42 (free GFP) under hand held UV light (Right) and the same leaves under white light (left). (B) Comparison on whole plant level between representative samples of constructs CTV33-23-HC-GFP-72 and CTV33-23-NIa-GFP-73 (fused GFP) and CTV33-23-BY-GFP-37, CTV33-23-G-GFP-40 and CTV33-23-B-GFP-42 (GFP under its own controller element behind p23 (Free GFP)) under hand held UV light (Right) and same plants under white light (Left). (C) Comparison between the abaxial (Lower) and adaxial (upper) leaf surfaces of the same representative leaf sample of constructs CTV33-23-HC-GFP-72 and CTV33-23-NIa-GFP-73 under hand held UV light (Right) and white light (Left).

FIG. 10 Western blot analysis of different expression vectors infiltrated into N. benthamiana leaves using GFP antibody. A=CTV9RΔp33GFP (GFP inserted under the BYV CP-CE controller element between CPm and CP (produces free GFP) (Tatineni et al., 2008)), B=CTV33-23-BY-GFP-HC-GUS-51, C=CTV33-23-G-GFP-NIa-GUS-54, D=Empty well; E=CTV33-Δ13-BY-GFP-NIa-GUS-78, F=CTV33-23-HC-GFP-72, G=CTV33-23-NIa-GFP-73.

FIG. 11 Hybrid gene (GFP/Protease/GUS fusion) replacement of p13 to create expression vectors. (A) Schematic representation of CTV9R Δ p33 and its modification to create expression vectors CTV33-Δ13-BYGFP-HC-GUS-77 and CTV33-Δ13-BYGFP-NIa-GUS-78 with the two fusion genes under the control of BYSV CP-CE with TEV HC-Pro and NIa spanned by their proteolysis recognition sequence separating GFP and GUS, respectively. (B) Activity of the reporter genes in N. benthamiana and Citrus macrophylla. (a.) Representative sample of N. benthamiana plant infected with either CTV33-Δ13-BYGFP-HC-GUS-77 or CTV33-Δ13-BYGFP-NIa-GUS-78 N. benthamiana under white light and (b.) the same plant under UV light (c.) Two pictures of peeled phloem bark pieces of C. macrophylla infected with construct CTV33-Δ13-BYGFP-NIa-GUS-78 under a flourescent stereoscope (d.) Representative sample of GUS activity in systemic N. benthamiana leaves, control leaf (Left) and infected leaf (right) (e.) Peeled bark phloem pieces and GUS solution of healthy C. macrophylla plant (f.) Peeled bark phloem pieces of C. macrophylla plant infected with construct CTV33-Δ13-BYGFP-NIa-GUS-78.

FIG. 12 Stability of Constructs in N. benthamiana. (A) Upper leaf from Agro-inoculated N. benthamiana plants carrying the binary vector CTV33-Δ13-BYGFP-HC-GUS-77 (GFP/HC-Pro/GUS) pictured under fluorescent microscope. (B) The same leaf was tested for GUS activity indicating almost perfect overlap between the two reporter genes.

FIG. 13 Hybrid gene (GFP/Protease/GUS fusion) between p23 and 3′NTR to create expression vectors. (A) Schematic representation of CTV9R Δ p33 and its modification to produce expression vectors CTV33-23-BY-GFP-HC-GUS-51 and CTV33-23-BY-GFP-NIa-GUS-52 has the BYSV CP-CE driving the hybrid genes that contain HC-Pro and NIa proteases respectively; CTV33-23-G-GFP-HC-GUS-53 (C53) and CTV33-23-G-GFP-NIa-GUS-54 (C54) are GLRaV-2 driven fusion genes that contain the HC-Pro and NIa proteases, respectively; CTV33-23-BY-GFP-HC-GUS-55 (C55) and CTV33-23-BY-GFP-NIa-GUS-56 (C56) are BYV driven fusion genes that contain HC-Pro and NIa proteases, respectively. (B) Northern blot hybridization analysis of transfected protoplast with wild type virus (WT), C53, C54, C55 and C56 constructs.

FIG. 14 Activity of reporter genes generated by insertion of the Hybrid gene (GFP/Protease/GUS fusion) behind p23. (A) Activity of the reporter genes in N. benthamiana. plants (a.) Representative sample of N. benthamiana plant infected with CTV33-23-BY-GFP-HC-GUS-51, CTV33-23-G-GFP-HC-GUS-53, CTV33-23-BY-GFP-NIa-GUS-52 or CTV33-23-G-GFP-NIa-GUS-54 under white light and (b.) the same plant under hand held UV light (c.) Representative sample of GUS activity in infected systemic N. benthamiana leaves and control leaves (tubes 1 &2 represent the solution before fixing and tissues in fixing solution, respectively from healthy leaves whereas 3&4 represent the solution and tissues from infected leaves, respectively, G tube is the GUS assay buffer (B.) Activity of reporter genes in C. macrophylla (a.) Picture of peeled phloem bark pieces of C. macrophylla infected with construct CTV33-23-BY-GFP-HC-GUS-51 under a flourescent stereoscope (b.) Peeled bark phloem pieces GUS activity in infected and healthy C. macrophylla plants (tubes 1 &2 represent the solution and tissues in fixing solution from healthy leaves whereas 3&4 represent the solution and tissues from infected leaves, respectively.

FIG. 15 Bimolecular Flouresence complementation (BiFC) prove of concept. (A) Schematic representation of CTVΔ Cla 333R (Gowda et al., 2001, Satyanarayana et al., 2003) replicon and its modification to create expression replicons: (a.) Insertion of both BiFC genes between p23 and 3′NTR giving rise to CTVp333R-23-BYbJunN-GbFosC and the controls with one gene behind p23, CTVp333R-23-BYbJunN(b.) or CTVp333R-23-GbFosC(c.). (B) Northern blot hybridization analysis of transfected protoplast with CTVp333R-23-BYbJunN-GbFosC (Lane a.), CTVp333R-23-BYbJunN (Lane c.) and CTVp333R-23-GbFosC (Lane b.). (C) Flourescence of a transfected protoplast when pictured under a stereoscope (Upper) or a laser scanning confocal microscope (lower) indicating the flourescence from the nucleus.

FIG. 16 BiFC gene replacement of p13 to produce CTV based expression vectors. (A) Schematic representation of CTV9RΔp33 and modification to produce vector CTV33-Δ13-BYbJunN-GbFosC-76 and the control vectors CTV33-23-G-bFosC-98 and CTV33-23-BY-bJunN-97 (insertion behind p23 nts 19020-19021). (B) Representative sample of N. benthamiana fluorescence in systemically infected plants.

FIG. 17 CTV based expression vector built to simultaneously express two genes from two controller elements. (A) Schematic representation of CTV9RΔp33 and its modification to produce expression vectors CTV33-23-BYbJunN-GbFosC-59 and CTV33-Δ13-BYbJunN-23-GbFosC-67. (B) Northern blot hybridization analysis of the RNA transfected protoplast with the wild type virus (WT,T), two clones of CTV33-Δ13-BYbJunN-23-GbFosC-67 (C67,T1 and T2) and two clones of CTV33-23-BY-bJunN-Gb-FosC-59 (C59, T3 and T4) probed with 3′NTR+p23 (Satyanarayana et al., 1999). (C) Flourescence of N. benthamiana plant parts under a flourescent stereo microscope (CTV33-23-BY-bJunN-Gb-FosC-59=a., b., c. and d; CTV33-Δ13-BYbJunN-23-GbFosC-67=e.) (a.) bud (b.) Corolla, (c.) systemic leaves, (d.) peeled bark phloem pieces and (e.) infiltrated leaf

FIG. 18 CTV based expression vector built to simultaneously express two genes from two controller elements. (A) Schematic representation of CTV9RΔp33 and its modification to produce expression vectors CTV33-Δ13-BYGUS-23-GGFP-71. (B) Northern blot hybridization analysis of the RNA transfected protoplast with the wild type virus (WT) and the CTV33-Δ13-BYGUS-23-GGFP-71 (C71) expression vector probed with 3′NTR+p23 (Satyanarayana et al., 1999). (C) Biological activity of reporter genes in N. benthamiana and Citrus. N. benthamiana plant under white light (a.) and hand held UV light (b.). (c.) GUS activity from healthy (tube 1 (assay solution) &2 (tissue) and infected N. benthamiana (tube 3 (assay solution) and tube 4 (tissue). (d.) Peeled bark phloem pieces under flourescent microscope and (e.) GUS assay activity in citrus similar to (c.)

FIG. 19 Western blot analysis of the different constructs in citrus to evaluate the expression of GFP and GUS. (A) GFP and CP antibody used to determine the level of expression of GFP relative to CP in citrus 708 plant infected with Δp33CTV9R (Tatineni et al., 2008), 1808 plant infected with BCN5 (Folimonov et al., 2007), 1916 plant infected with CTV33-23-G-GFP-40, 1874 plant infected with CTV33-23-BY-GFP-37, 1934, 1935, 1937 infected with CTV33-13-BY-GFP-69, 1931 and 1939 infected with construct CTV33-Δ13-G-GFP-65 and CTV33-Δ13-B-GFP-66, respectively. (B) GUS and CP antibody used to determine the level of expression of GUS relative to CP in citrus 2084, 2085, 2086, 2087 plants infected with construct CTV33-Δ13-BYGUS-61, 2132 plant infected with construct CTV33-23-BYGUS-60, 2096 plant infected with expression vector CTV33-Δ13-BYGFP-NIa-GUS-78, E=empty well and buffer=−iveC.

FIG. 20 CTV based expression vector built to simultaneously express four genes from four controller elements. (A) A schematic representation of CTV9R. (B) Modification of CTV9R to create expression vector CTVΔ13-BRFP-GbFosC-BYbJunN-CTMVCP-118 which expresses 4 genes from different locations within the CTV genome. The first gene is the red flourescent protein gene (tagRFP) expressed from between the minor and major coat proteins under the control of the Beet yellows virus (BYV) coat protein controller element (CP-CE), the second and third genes are the truncated mammalian transcription factors bFos and bJun fused to the C and N terminus of EYFP (Hu et al., 2002) under the control of Grape vine leaf roll associated virus-2 (GLRaV-2) and Beet yellow stunt virus (BYSV) CP-CE respectively replacing the p13 gene and the fourth gene is the CP of TMV expressed from behind p23 under the control of the duplicated major CP-CE of CTV.

FIG. 21 CTV based expression vector built to simultaneously express three genes from three controller elements. (A) A schematic representation of CTV9R. (B) Modification of CTV9R to create expression vector CTVΔ13-GbFosC-BYbJunN-CTMVCP-129 which expresses 3 genes from different locations within the CTV genome. The first and second genes are the truncated mammalian transcription factors bFos and bJun fused to the C and N terminus of EYFP (Hu et al., 2002) under the control of Grape vine leaf roll associated virus-2 (GLRaV-2) and Beet yellow stunt virus (BYSV) CP-CE respectively replacing the p13 gene and the fourth gene is the CP of TMV expressed from behind p23 under the control of the duplicated major CP-CE of CTV.

FIG. 22 CTV based expression vector built to simultaneously express three genes from three controller elements. (A) A schematic representation of CTV9R. (B) Modification of CTV9R to create expression vector CTV-BRFP-BYGFP-CTMVCP-117 which expresses 3 genes from different locations within the CTV genome. The first gene is the red flourescent protein gene (tagRFP) expressed from between the minor and major coat proteins under the control of the Beet yellows virus (BYV) coat protein controller element (CP-CE), the second gene is the Green fluorescent protein (GFPC3) under the control of Beet yellow stunt virus (BYSV) CP-CE inserted between p13-p20 gene and the third gene is the CP of TMV expressed from behind p23 under the control of the duplicated major CP-CE of CTV.

FIG. 23 CTV based expression vector built to simultaneously express three genes from three controller elements. (A) A schematic representation of CTV9R. (B) Modification of CTV9R to create expression vector CTV-BASL-BYPTA-CP7-119 which expresses 3 genes from different locations within the CTV genome. The first gene is a lectin from Allium sativum (ASL) expressed from between the minor and major coat proteins under the control of the Beet yellows virus (BYV) coat protein controller element (CP-CE), the second gene is an agglutinin from Pinellia ternata (PTA) under the control of Beet yellow stunt virus (BYSV) CP-CE inserted between p13-p20 gene and the third gene is an antimicrobial peptide from Tachypleus tridentatus (P7) expressed from behind p23 under the control of the duplicated major CP-CE of CTV.

FIG. 24 CTV based expression vector built to simultaneously express three genes from three controller elements. (A) A schematic representation of CTV9R. (B) Modification of CTV9R to create expression vector CTV-BASL-BYPTA-CP10-120 which expresses 3 genes from different locations within the CTV genome. The first gene is a lectin from Allium sativum (ASL) expressed from between the minor and major coat proteins under the control of the Beet yellows virus (BYV) coat protein controller element (CP-CE), the second gene is an agglutinin from Pinellia ternata (PTA) under the control of Beet yellow stunt virus (BYSV) CP-CE inserted between p13-p20 gene and the third gene is an antimicrobial peptide from Sus scorfa (P10) expressed from behind p23 under the control of the duplicated major CP-CE of CTV.

FIG. 25 CTV based expression vector built to simultaneously express three genes from three controller elements. (A) A schematic representation of CTV9R. (B) Modification of CTV9R to create expression vector CTV-BASL-BYP10-CP7-131 which expresses 3 genes from different locations within the CTV genome. The first gene is a lectin from Allium sativum (ASL) expressed from between the minor and major coat proteins under the control of the Beet yellows virus (BYV) coat protein controller element (CP-CE), the second gene is an antimicrobial peptide from Sus scorfa (P10) under the control of Beet yellow stunt virus (BYSV) CP-CE inserted between p13-p20 gene and the third gene is a second antimicrobial peptide from Tachypleus tridentatus (P7) expressed from behind p23 under the control of the duplicated major CP-CE of CTV.

FIG. 26 CTV based expression vector built to simultaneously express three genes from three controller elements. (A) A schematic representation of CTV9RΔp33. (B) Modification of CTV9R Δp33 to create expression vector CTV33-BGFP-BYGUS-GTMVCP-79 which expresses 3 genes from different locations within the CTV genome. The first gene is a green flourescent protein expressed from between the minor and major coat proteins under the control of the Beet yellows virus (BYV) coat protein controller element (CP-CE), the second gene is a β-Glucuronidase (GUS) gene from Eisherchia coli under the control of Beet yellow stunt virus (BYSV) CP-CE inserted between p13-p20 gene and the third gene is the CP of TMV expressed from behind p23 under the control of Grape vine leaf roll associated virus-2 (GLRaV-2) CP-CE.

FIG. 27 CTV based expression vector built to simultaneously express four genes from four controller elements. (A) A schematic representation of CTV9RΔp33. (B) Modification of CTV9RΔp33 to create expression vector CTV33-BGFP-GbFosC-BYbJunN-81 which expresses 3 genes from different locations within the CTV genome. The first gene is the green flourescent protein gene (GFPC3) expressed from between the minor and major coat proteins under the control of the Beet yellows virus (BYV) coat protein controller element (CP-CE), the second and third genes are the truncated mammalian transcription factors bFos and bJun fused to the C and N terminus of EYFP (Hu et al., 2002) under the control of Grape vine leaf roll associated virus-2 (GLRaV-2) and Beet yellow stunt virus (BYSV) CP-CE respectively. The bFosC gene is inserted behind p23 gene.

FIG. 28 CTV based expression vector built to simultaneously express four genes from four controller elements. (A) A schematic representation of CTV9RΔp33. (B) Modification of CTV9RΔp33 to create expression vector CTV33-Δ13-BGFP-BYbJunN-GbFosC-82 which expresses 3 genes from different locations within the CTV genome. The first gene is the green flourescent protein gene (GFPC3) expressed from between the minor and major coat proteins under the control of the Beet yellows virus (BYV) coat protein controller element (CP-CE), the second gene is the truncated mammalian transcription factor bJun to the N terminus of EYFP (bJunN) (Hu et al., 2002) under the control of Beet yellow stunt virus (BYSV) CP-Cereplacing the p13 gene of CTV and the third gene is the truncated mammalian transcription factor bFos fused to the C-terminus of EYFP (bFosC) under the control of Grape vine leaf roll associated virus-2 (GLRaV-2) CP-CE inserted behind p23.

FIG. 29 Negative staining Electron microscopy pictures from leaf dips of infiltrated N. benthamiana Leaves. (A) Leaf dips from infiltrated N. benthamiana leaves with construct CTV33-BGFP-BYGUS-GTMVCP-79 reveals the formation of CTV vector virions and TMV pseudo virions indicating the expression of the TMV coat protein gene. (B) Leaf dip from Infiltrated N. benthamiana leaves with construct CTV33-Δ13-BGFP-BYbJunN-GbFosC-82 reveals the formation of virions.

DETAILED DESCRIPTION

The early development of viral vectors was aimed at the inexpensive production of high levels of specialty proteins that could be scaled up in the field. The first attempt at a plant viral vector utilized Cauliflower mosaic virus, a dsDNA virus (Brisson et al., 1984; Gronenborn et al., 1981). However, this vector was too unstable to be useful (Fütterer et al., 1990). The development of reverse genetics systems amenable for manipulation of RNA viruses made many more viruses candidates for vector development (Ahlquist et al., 1984). There was considerable controversy concerning the value of RNA viruses for vectors (Siegel, 1983, 1985; Van Vluten-Dotting, 1983 Van Vluten-Dotting et al., 1985). It was argued that the lack of proof-reading of the RNA virus replicases would result in too rapid sequence drift to maintain foreign sequences during replication. However, subsequent development and use of RNA virus-based vectors demonstrated that this concern was overstated.

Ongoing efforts have been underway to create virus-based vectors for citrus trees based on Citrus tristeza virus (CTV). CTV has the largest reported RNA of a plant virus of approximately 20 kb (Karasev et al., 1995; Pappu et al., 1994). It has two conserved gene blocks associated with replication and virion formation (Karasev, 2000). The replication gene block occupies the 5′ half of the genome. Its proteins are expressed from the genomic RNA via a poly protein strategy with a +1 ribosomal frame shift to occasionally express the RNA dependent RNA polymerase (Karasev et al., 1995). The filamentous virions of CTV are encapsidated by two coat proteins, with the major coat protein (CP) encapsidating about 97% of the virion and the 5′ ˜700 nts encapsidated by the minor coat protein (CPm) (Satyanarayana et al., 2004). Virion formation is a complex process requiring two proteins (Hsp70h and p61) in addition to the coat proteins (Satyanarayana et al., 2000, 2004; Tatineni et al., 2010). These four genes as well as the 6 remaining genes are differentially expressed via a nested set of 3′ co-terminal sub genomic (sg) RNAs (Hilf et al., 1995). Upstream of each ORF there is a controller element (CE) that determines the transcription level (Gowda et al., 2001). Levels of transcription are also associated with the +1 transcription start site (Ayllón et al., 2003), the presence of a non-translated region upstream of the ORF (Gowda et al., 2001), and the closeness of the ORF to the 3′ terminus (Satyanarayana et al., 1999).

The first generations of CTV vector examined three different strategies that were fusion of the CP gene, insertion of an extra gene, and replacement of the p13 ORF (Folimonov et al., 2007). Replacement of the p13 ORF and fusion to the coat protein ORF did not result in effective vectors, but the addition of an extra gene resulted in viable vectors that produce relative large amounts of foreign gene and were stable in citrus trees for years. However, the first efforts in designing vectors based on CTV examined only a few of the many possibilities for expressing foreign genes in this large virus. In this work, the inventors attempted to examine the limitations of CTV to be manipulated into a vector. The inventors examined whether the virus allowed insertions in different positions within the genome and which resulted in maximal expression with different sizes of inserts. The inventors also examined whether different fusion strategies with different viral genes are viable and whether multiple foreign genes can be expressed. The CTV constructs disclosed herein are amazingly tolerant to manipulation at several positions within the genome giving a multitude of different vector strategies that are viable.

Once citrus is infected with a CTV vector containing a foreign gene, it is easy to move the vector to other citrus trees by grafting. However, a limitation of the CTV vector system is the difficulty of initially getting citrus infected with new vector constructs. Directly inoculating citrus from the cDNA clones, either by agro-inoculation, particle bombardment, or mechanical inoculation with RNA transcripts is extremely difficult and unpredictable (Gowda et al., 2005; Satyanarayana et al., 2001). An alternative has been to inoculate with virions purified from Nicotiana benthamiana protoplasts (Folimonov et al., 2007; Robertson et al., 2005; Satyanarayana et al., 2001; Tatineni et al., 2008). However, infection of only approximately 0.01-0.1% of protoplasts with in vitro transcribed RNA has been achieved (Satyanarayana et al., 2001). Yet, since virions are much more infectious to the protoplasts than RNA (Navas-Castillo et al., 1997), the inventors were able to amplify the infection by sequential passage in protoplasts (Folimonov et al., 2007; Robertson et al., 2005; Satyanarayana et al., 2001; Tatineni et al., 2008). Although workable, this is an extremely difficult system. The inventors are now able to agro-inoculate N. benthaminana plants that result in systemic infection. This result allows analysis of the vector constructs more quickly in these plants and provides copious amounts of recombinant virus for inoculation of citrus. Thus, the inventors report the activity of the different vector constructs in N. benthamina and Citrus.

According to one embodiment, the invention pertains to a CTV viral vector engineered to comprise a gene cassette comprising a polynucleotide encoding a heterologous polypeptide. The gene cassette is located at a targeted position on the CTV genome. In a more specific embodiment, the CTV viral vector is engineered such that the gene cassette is positioned at CTV genome regions p13-p20, p20-p23 or p23-3′NTR. In other embodiments, the CTV viral vector is engineered to include multiple genes at one or multiple positions. It is shown herein that CTV viral vectors can successfully be engineered to include up to 3 or at least 4 genes that are expressible by the vector, while maintaining the proper function and infectivity of the vector.

In related embodiments, the invention pertains to a plant that includes at least one cell transfected with the CTV viral vector engineered to comprise a gene cassette comprising a polynucleotide encoding a heterologous polypeptide, the CTV viral vector engineered such that one or more gene cassettes are positioned at CTV genome regions p13-p20, p20-p23 or p23-3′NTR. Other related embodiments pertain to methods of expressing at least one heterologous polypeptide in a plant by infecting the plant with the specified vector.

In a further embodiment, the invention is directed to a CTV viral vector engineered to comprise at least one gene cassette that includes a polynucleotide encoding a heterologous polypeptide, wherein the CTV viral vector engineered such that the gene cassette is inserted in place of the CTV p13 gene. In related embodiments, the invention pertains to a plant that includes at least one cell transfected with the CTV viral vector or to methods of expressing the heterologous polypeptide in a plant by infecting the plant with the specified vector.

In another embodiment, the invention relates to a CTV viral vector engineered to comprise at least one gene cassette comprising a polynucleotide encoding heterologous polypeptide and IRES sequence conjugated thereto. In related embodiments, the invention pertains to a plant that includes at least one cell transfected with the CTV viral vector or to methods of expressing the heterologous polypeptide in a plant by infecting the plant with the specified vector.

In further embodiments, the invention relates to a CTV viral vector engineered to comprise a gene cassette comprising a polynucleotide sequence with continuous amino acid codons extending from the p23 ORF encoding a first heterologous polypeptide (protease) with cleavage sites on each side plus a second heterologous polypeptide. In related embodiments, the invention pertains to a plant that includes at least one cell transfected with the CTV viral vector or to methods of expressing the heterologous polypeptide in a plant by infecting the plant with the specified vector.

In further embodiments, the polynucleotide further comprises a sequence encoding a first control element upstream of said first heterologous polypeptide, a second sequence encoding a protease with cleavage sites engineered on each side, and a sequence encoding a second heterologous polypeptide.

According to another embodiment, the invention is directed to CTV viral vector engineered to comprise a first gene cassette comprising a polynucleotide sequence encoding a first heterologous polypeptide and a first controller element upstream of said first heterologous polypeptide encoding sequence; and a second gene cassette comprising a polynucleotide sequence encoding a second heterologous polypeptide and a second control element upstream of said second heterologous polypeptide encoding sequence. Optionally, the CTV viral vector further comprises a third gene cassette comprising a polynucleotide sequence encoding a third heterologous polypeptide and a third controller element upstream of said third heterologous polypeptide encoding sequence; and a fourth gene cassette comprising a polynucleotide sequence encoding a fourth heterologous polypeptide and a fourth controller element upstream of said fourth heterologous polypeptide encoding sequence. Those skilled in the art will appreciate that additional gene cassettes can be added to the vector so long as function and infectivity of the vector is maintained. In related embodiments, the invention pertains to a plant that includes at least one cell transfected with the CTV viral vector or to methods of expressing the heterologous polypeptide in a plant by infecting the plant with the specified vector.

Examples of controller elements (CE) useful in accordance with the teachings herein include but are not limited to controller elements homologous to CTV or heterologous control elements. Heterologous controller elements include, but are not limited to, coat protein controller elements (CP-CEs) of three closteroviruses: Beet yellows virus (BYV) (94 nts from 13547-13640 Genbank accession # AF190581) (Peremyslov et al., 1999), Beet yellow stunt virus (BYSV) (101 nts from 8516-8616 Genbank accession # U51931) (Karasev et al., 1996) and Grape vine leaf roll associated virus-2 (GLRaV-2) (198 nts from 9454-9651 Genbank accession # DQ286725). It will be evident to those skilled in the art, in view of the teachings herein, that other controller elements may be implemented, and in particular control elements having strong promoter like activity.

These and other embodiments are further described below and encompassed within the appended claims.

Materials and Methods for Examples 1-7 Below Plasmids Construction

pCTV9RΔp33 and pCTVΔCla 333R (Gowda et al., 2001; Satyanarayana et al., 1999, 2000, 2003; Tatineni et al., 2008) were used as base plasmids for developing all expression vectors that were used in the protoplast reverse genetics system. The numbering of the nucleotides (nts) is based on the full length T36 clone (Genbank Accession # AY170468) (Satyanarayana et al., 1999, 2003). CTVp333R-23-ITEV-GFP and CTVp333R-23-I3×ARC-GFP (FIG. 7A) were created by fusing 5′ non translated region (NTR) of Tobacco etch virus (TEV) (nucleotides (nts) 2-144 Genbank accession # DQ986288) (Carrasco et al., 2007) and 3×ARC-1 (Active ribosome complementary sequence) (Akergenov et al., 2004) behind the p23 stop codon (between nts19020-19021 in full length T36 clone) using overlap extension polymerase chain reaction (PCR) (Horton et al., 1989). For creating expression vectors by gene addition and/or substitution at different locations, heterologous controller elements (CE) were selected from coat protein controller elements (CP-CEs) of three closteroviruses: Beet yellows virus (BYV) (94 nts from 13547-13640 Genbank accession # AF190581) (Peremyslov et al., 1999), Beet yellow stunt virus (BYSV) (101 nts from 8516-8616 Genbank accession # U51931) (Karasev et al., 1996) and Grape vine leaf roll associated virus-2 (GLRaV-2) (198 nts from 9454-9651 Genbank accession # DQ286725) to drive the ORFs for cycle 3 GFP (GFP) (Chalife et al., 1994; Crameri et al., 1996), β-Glucuronidase (GUS) ORF of Eisherchia coli, bFosYC155-238 (bFosC), bJunYN1-154 (bJunN). CTVp333R-23-BYbJunN-GbFosC, CTVp333R-23-BYbJunN, CTVp333R-23-GbFosC (FIG. 15A) were created by overlap extension PCR from plasmids pBiFC-bFosYC155 and pBiFC-bJunYN155 (Hu et al., 2002) and CTV9R (Satyanarayana et al., 1999; 2003). Since two NotI sites exist within the bimolecular fluorescence genes (BiFC), the overlap extension PCR products were digested partially by NotI restriction endonuclease. The PCR products were introduced into a StuI and NotI digested pCTVΔCla 333R (FIGS. 7A & 3-15A).

The expression vectors created in pCTV9RΔp33 were introduced into the CTV genome by digesting the plasmid with PstI (nts 17208-17213) and NotI or StuI (introduced behind 19,293 the final CTV nucleotide). Overlap extension PCR (Horton et al., 1989) was used to introduce the appropriate genes at the different locations. Replacement of the p13 gene was done by deletion of nts 17293-17581 in the p13 ORF and (CE) by overlap extension PCR (FIGS. 3-1A, 3-2A, 3-11A, 3-16A, 3-17A & 3-18A). Similarly, insertion between p13 and p20 (nts #17685-17686) (FIG. 3A), p20-p23 (nts #18312-18313) (FIG. 4A) and p23-3′NTR (nts #19020-19021) (FIGS. 3-5A, 3-6A, 3-13A, 3-16A, 3-17A & 3-18A) were done by overlap extension PCR. A hybrid gene created by fusing the GFP ORF (Chalife et al., 1994; Crameri et al., 1996) and GUS ORF separated by the HC-Pro protease motif (nts 1966-2411 Genbank accession # M11458)(Allison et al., 1985; Carrington et al., 1989) and its recognition sequence fused to the N terminus of GUS (ATGAAAACTTACAATGTTGGAGGGATG (SEQ ID NO: 1) (nts 2412-2438 Genbank accession # M11458) (Allison et al., 1985; Carrington et al., 1989) (Amino acid sequence (A.A.) MKTYNVG,GM) (SEQ ID NO: 2) (arrow indicate processing site) and C terminus of GFP (ATGAAGACCTATAACGTAGGTGGCATG) (SEQ ID NO: 3) was created and inserted behind p23 (FIG. 13A) or as replacement of p13 (FIG. 3-11A) under different controller elements. A similar hybrid gene was created by using the Nla protease motif of TEV (nts 6270-6980 Genbank accession # M11458) (Allison et al., 1985) and its recognition sequence (GAGAATCTTTATTTTCAGAGT (SEQ ID NO: 4) (nts 8499-8519 Genbank accession # M11458) (A.A. ENLYFQ↓S) (SEQ ID NO: 5) (arrow indicate processing site) (Carrington and Dougherty, 1988) at C terminus of GFP and GAAAACCTATACTTCCAATCG (SEQ ID NO: 6) at N terminus of GUS). The redundancy of the amino acid genetic code was used to eliminate complete duplication of the nucleotide sequences of the recognition motifs. A similar strategy was used to create a hybrid gene between p23 ORF and GFP ORF in construct CTV33-23-HC-GFP-72 and CTV33-23-Nla-GFP-73 (FIG. 8). Switching the recognition motif of the proteases generated control vectors CTV33-23-HCØ-GFP-74 and CTV33-23-NlaØ-GFP-75 (FIG. 8).

The binary plasmid pCAMBIACTV9R (Gowda et al., 2005) was modified to eliminate the p33 gene by deleting nts 10858-11660 (Satyanarayana et al., 2000; Tatineni et al., 2008) and introducing a SwaI site behind the ribozyme engineered based on subterranean clover mottle virusoid (Turpen et al., 1993). PCR products amplified from the expression vectors in the pCTV9RΔp33 back-bone were introduced into the modified binary plasmid pCAMBIACTV9RΔp33 digested with PstI (Forward primer C-749) and SwaI (Reverse primer C-1894). When introducing the bimolecular fluorescence complementation (BiFC) genes into constructs CTV33-23-BYbJunN-GbFosC-59 (FIG. 17), CTV33-Δ13-BYbJunN-23-GbFosC-67 (FIG. 17), CTV33-Δ13-BYbJunN-GbFosC-76 (FIG. 16), CTV33-23-GbFosC-98 (FIG. 16) and CTV33-23-BYbJunN-97 (FIG. 16) a primer was used switching the PstI to the compatible NsiI (primer C-2085) for ease of cloning (the bFosC gene sequence contains one PstI site while the bJunN gene sequence contains two PstI sites). Preliminary screening for the right inserts in the different expression vectors was done by restriction digestion using the appropriate enzymes. The junctions where the foreign genes were introduced into the expression vectors were confirmed by sequencing at the Interdisciplinary Center for Biotechnology Research (ICBR) (University of Florida, Gainesville, Fla.). All primers are listed in Table 1-1.

TABLE 1-1 List of primers used in building expression vector Primer name Sequence 5′-3′* SEQ ID NO: Description* C-749 AGT CCT CGA GAA  7 3′end of p18 (CTV T36 CCA CTT AGT TGT clones nts # 17121- TTA GCT ATC 17145) with an added XhoI site before nt #17121) (downstream of this primer there exist within CTV genome a PstI site (nts 17208- 17213 of CTV T36) used for cloning) (F.P.) C-1358 TTA TGC GGC CGC  8 3′end of 3′NTR (nts AGG CCT TGG ACC 19,270-19,293 of CTV TAT GTT GGC CCC T36 clone) contain (StuI CCA TAG and NotI sites) (R.P.) C-1568 TAA TCG TAC TTG  9 5′end of GFP (nts 1-21) AGT TCT AAT ATG with extension into 3′ GCT AGC AAA GGA end of BYV CP IR (nts # GAA GAA 13620-13640 Genbank Accession # AF190581) (F.P.) C-1894 GCC GCA CTA GTA 10 3′end of 3′NTR (nts TTT AAA TCC CGT 19,262-19,293 of CTV TTC GTC CTT TAG T36 clone) with GGA CTC GTC AGT extensions that include a GTA CTG ATATAA ribozyme of GTA CAG ACT GGA subterranean clover CCT ATG TTG GCC virusoid (underlined) CCC CAT AGG GAC (Turpen et al., 1993) and AGT G SwaI and SpeI restriction sites (R.P.) C-1973 ATG GAT GAG CTC 11 5′end of 3′NTR (nts TAC AAA TGA TTG 19021-19043 of CTV AAGTGG ACG T36 clone) with GAATAA GTT CC extension into GFP 3′end (nts 700-720) (F.P.) C-1974 GGA ACT TAT TCC 12 3′end of GFP (nts 700- GTC CACTTC AAT 720) with extension into CAT TTG TAG 5′end of 3′NTR (nts AGCTCA TCC AT 19021-19043 of CTV T36 clone) (R.P.) C-1975 GCA CGT TGT GCT 13 GLRaV-2 intergenic ATA GTA CGT GCC region of CP (nts 9568- ATA ATA GTG AGT 9651 Genbank GCT AGC AAA Accession number GTATAA ACG CTG DQ286725) (F.P.) GTGTTT AGC GCA TAT TAA ATA CTA ACG C-1976 CAG CTT GCT TCT 14 BYSV CP intergenic ACCTGA CAC AGT region of (nts 8516-8616 TAA GAA GCG Genbank accesion # GCATAA ATC GAA U51931) (F.P.) GCC AAA CCCTAA ATT TTG CAA CTC GAT CAATTG TAA CCT AGA GCG AAGTGC AAT CA C-1977 TTT AGC GCA TAT 15 5′end of GFP (nts 1-21) TAA ATA CTA ACG with extension into the ATG GCT AGC AAA 3′end of GLRaV-2 CP GGA GAA GAA intergenic region (nts 9628-9651 Genbank Accession number DQ286725) (F.P.) C-1979 ACT GTG TCA GGT 16 3′end of p23 (nts AGA AGC AAG CTG 19,000-19,020 of CTV TCA GAT GAA GTG T36 clone) with GTGTTC ACG extension into 5′end of BYSV CP IR (nts 8516- 8539 Genbank accesion # U51931) (R.P.) C-1982 TTG G AT TTA GGT 17 Sp6 promoter GAC ACT ATA G TG (underlined and Italics) GAC CTATGTTGG with 3′ end of 3′NTR (nts CCC CCC ATA 19271-19293 of CTV T36 clone) used to develop dig labeled probe (R.P.) C-1983 GTA ACCTAG AGC 18 5′end of GFP (nts 1-23) GAA GTG CAA TCA with extension into 3′end ATG GCT AGC AAA of BYSV IR of CP (nts GGA GAA GAA 8593-8616 Genbank Accession # U51931) (F.P.) C-1984 GCC TAA GCT TAC 19 3X active ribosome AAA TAC TCC CCC complementary ACA ACA GCT TAC sequence (3XARC-1 nts AAT ACT CCC CCA 1-86) (Akbergenov et CAC AGC TTA CAA al., 2004) (F.P.) ATA CTC CCC CAC AAC AGCTTG TCG AC C-1985 CTC CGT GAA CAC 20 5′ end of TEV 5′NTR CACTTC ATC TGA (nts 1-21 Genbank AAA TAA CAA ATC Accession # M11458) TCA ACA CAA with extension into 3′ end of p23 (nts 18997- 19020 of CTV T36 clone) (F.P.) C-1986 TTG TGT TGA GAT 21 3′end of p23 (nts 18997- TTG TTA TTT TCA 19020 of CTV T36 GAT GAA GTG GTG clone) with extension TTC ACG GAG into 5′ end of TEV 5′NTR (nts 1-21 Genbank Accession # M11458) (R.P.) C-1989 GGA GTATTT GTA 3′end of p23 (nts 18997- AGCTTA GGC TCA 19020 of CTV T36 GAT GAA GTG clone) with extension GTGTTC ACG GAG into 5′end of 3XARC-1 (nts 1-21) (R.P.) C-1990 CCC CAC AAC 23 5′end of GFP (nts 1-25) AGCTTG TCG ACA with extension into 3′end TGG CTA GCA AAG of 3XARC-1 (nts 66-86) GAG AAG AAC TTT (F.P.) C-2007 CGT GAA CAC 24 BYV 3′end of CPm and CACTTC ATC TGA the intergenic region of TTC GAC CTC GGT CP (nts 13547-13570 CGT CTT AGT TAA Genbank Accession # AF190581) with extension into p23 3′end (nts 19,000-19,020 of CTV T36 clone) (F.P.) C-2008 TTA ACT AAG ACG 25 3′end of p23 (nts ACC GAG GTC GAA 19,000-19,020 of CTV TCA GAT GAA GTG T36 clone) with GTG TTC ACG extension into the 3′end of CPm and CP intergenic region of BYV (nts 13,547-13,570 Genbank Accession # AF190581) (R.P.) C-2009 GGC GAT CAC GAC 26 GLRaV-2 3′end of CPm AGA GCC GTGTCA and 5′end of CP ATT GTC GCG GCT intergenic region (nts AAG AAT GCT GTG 9454-9590 Genbank GAT CGC AGC GCT Accession number TTC ACT GGA GGG DQ286725) (F.P.) GAG AGA AAA ATA GTT AGT TTG TAT GCCTTA GGA AGG AACTAA GCA CGT TGT GCT ATA GTA CGT GC C-2010 TGA CAC GGC TCT 27 3′end of p23 (nts GTC GTG ATC GCC 19,000-19,020 of CTV TCA GAT GAA GTG T36 clone) with GTGTTC ACG extension into the 3′end of GLRaV-2 CPm coding sequence (nts 9454- 9477 Genbank Accession # DQ286725) (R.P.) C-2011 GCC ACC TAC GTT 28 3′end of GFP (nts 697- ATA GGT CTT CAT 717) with extension into TTT GTA GAG CTC the TEV HC-Pro ATC CAT GCC protease recognition sequence (nts 2412- 2435 (genetic code redundancy used to eliminate duplication Genbank Accession # M11458) (R.P.) C-2012 AAG ACC TAT AAC 29 5′ end of TEV HC Pro GTA GGT GGC ATG protease motif (nts AAG GCT CAATAT 1959-1979 Genbank TCG GAT CTA Accession # M11458) with extension into the HC-Pro recognition sequence (nts 2415- 2438 genetic code redundancy used to eliminate duplication Genbank Accession # M11458) (F.P.) C-2013 ATG AAA ACT TAC 30 5′end of GUS (nts 4-21) AAT GTT GGA GGG with extension into the ATG TTA CGT CCT TEV HC-Pro recognition GTA GAA ACC sequence and 3′ end of TEV HC-Pro protease motif (nts 2412-2438 Genbank Accession # M11458) (F.P.) C-2014 GGT TTC TAC AGG 31 TEV HC-Pro recognition ACG TAA CAT CCC sequence (nts 2412- TCC AAC ATT GTA 2438 Genbank AGT TTT CAT Accession # M11458) with extension into the 5′ end of GUS ORF sequence (nts 4-21) (R.P.) C-2015 CCG CAG CAG GGA 32 5′ end of 3′NTR (nts GGC AAA CAA TGA 19021-19041 of CTV TTG AAGTGG ACG T36 clone) with GAA TAA GTT extension into the 3′ end of GUS ORF (nts 1789- 1812) (F.P.) C-2016 AAC TTA TTC CGT 33 3′ end of GUS (nts 1789- CCA CTT CAA TCA 1812) with extension TTG TTT GCCTCC into the 5′end of 3′NTR CTG CTG CGG (NTs 19021-19041 of CTV T36 clone) (R.P.) C-2017 CTT ACT CTG AAA 34 3′end of GFP (nts 697- ATA AAG ATT CTC 717) with extension into TTT GTA GAG CTC the 5′end of TEV-NIa ATC CAT GCC protease recognition sequence (nts 8499- 8519 Genbank Accession # M11458) and 5′ end of TEV NIa protease motif (nts 6270-6272 Genbank Accession # M11458) (R.P.) C-2018 AAA GAG AAT CTT 35 5′ end of TEV NIa TAT TTT CAG AGT protease motif (nts AAG GGA CCA CGT 6270-6290 Genbank GAT TAC AAC Accession # M11458) with extension into its recognition sequence (nts 8499-8519 Genbank Accession # M11458) and 3′ end of GFP (nts 715-717) (F.P.) C-2019 CGA TTG GAA GTA 36 3′end of TEV NIa motif TAG GTT TTC TTG (nts 6961-6980 Genbank CGA GTA CAC CAA Accession # M11458) TTC ACT CAT with extension into NIa recognition sequence (nts 8499-8519 Genbank Accession # M11458 genetic code redundancy used to eliminate duplication) (R.P.) C-2020 CAA GAA AAC CTA 37 5′end of GUS with TAC TTC CAA TCG extension into the TEV ATG TTA CGT CCT NIa recognition GTA GAA ACC sequence (nts 8499- 8519 Genbank Accession # M11458 genetic code redundancy used to eliminate duplication) and 3′ end of TEV NIa protease motif (nts 6978-6980 Genbank Accession # M11458) (F.P.) C-2021 GTC ACT TTG TTT 38 5′end of BYSV CP IR AGC GTG ACT TAG (nts 8516-8536 Genbank CAG CTT GCT TCT Accession # U51931) ACC TGA CAC with extension into 3′end of p18 (nts 17269-17292 of CTV T36 clone) (F.P.) C-2022 GTG TCA GGT AGA 30 3′ end of p18 (nts AGC AAG CTG CTA 17289-17292 of CTV AGT CAC GCT AAA T36 clone) with CAA AGT GAC extension into 5′ end BYSV CP IR (nts 8516- 8536 Genbank Accession # U51931) (R.P.) C-2023 TTA GTC TCT CCA 40 5′end of BYSV CP TCT TGC GTG TAG IR (nts 8516-8536 CAG CTT GCT TCT Genbank Accession # ACC TGA CAC U51931) with extension into the 3′end of p20 (nts 18286-18309 of CTV T36 clone) (F.P.) C-2024 GTG TCA GGT AGA 41 3′end of p20 (nts 18286- AGC AAG CTG CTA 18309 of CTV T36 CAC GCA AGATGG clone) with extension AGA GAC TAA into the 5′ end of BYSV CP IR (nts 8516-8536 Genbank Accession # U51931) (R.P.) C-2025 ATG GAT GAG CTC 42 3′end of p13 ORF (nts TAC AAA TGA--GTT 17581-17604 of CTV TCA GAA ATT GTC T36 clone) with GAATCG CAT extension into the 3′end of GFP ORF (nts 700- 720) (F.P.) C-2026 ATG CGA TTC GAC 43 3′end of GFP ORF (nts AAT TTC TGA AAC 700-720) with extension TCA TTT GTA GAG into the 3′end of p13 CTC ATC CAT ORF (nts 17581-17604 of CTV T36 clone) (R.P.) C-2027 ATG GAT GAG CTC 44 5′end of p23 IR (nts TAC AAA TGA GTT 18,310-18,330 of CTV AAT ACG CTT CTC T36 clone) with AGA ACG TGT extension into 3′ end of GFP (nts 700-720) (F.P.) C-2028 ACA CGT TCT GAG 45 3′end of GFP (nts 700- AAG CGT ATT AAC 720) with extension into TCA TTT GTA GAG p23 IR (nts 18310-18330 CTC ATC CAT of CTV T36 clone) (R.P.) C-2029 TTT AGC GCATAT 46 5′ end of HA TAG TAA ATA CTA ACG (21 nts) in pHA-CMV ATG TAC CCATAC carrying bFos (AA 118- GAT GTT CCA 210)-YC (AA 155-238) (Hu et al., 2002) with extension into the GLRaV-2 CP IR 3′ end (nts 9628-9551 Genbank Accession number DQ286725) (F.P.) C-2030 TCG AAC ATC 47 3′ end of CPm GLRaV-2 GTATGG GTA CAT (nts 9628-9651 Genbank CGT TAGTAT TTA Accession number ATATGC GCT AAA DQ286725) with extension into 5′ end of HA tag (21 nts) in pHA- CMV carrying bFos (AA 118-210)-YC (AA 155- 238) (Hu et al., 2002) (R.P.) C-2031 ACT GTGTCA GGT 48 3′end EYFP-YC (AA AGA AGC AAG CTG 232-238) (Hu et al., TTA CTT GTA CAG 2002) with extension into CTC GTC CAT the BYSV CP 5′IR (nts 8516-8539 Genbank Accession # U51931) (R.P.) C-2032 GTA ACCTAG AGC 49 5′end of FLAG tag GAA GTG CAATCA (21 nts) from pFLAG- ATG GACTAC AAA CMV2 carrying bJunN GAC GAT GAC (Hu et al., 2002) with extension into the 3′end of BYSV CP IR (nts 8593-8616 Genbank Accession # U51931) (F.P.) C-2051 GTC ACT TTG TTT 50 3′end of GLRaV-2 CPm AGC GTG ACT TAG (nts 9454-9474 Genbank GGC GAT CAC GAC Accession # DQ286725) AGA GCC GTG with extension into 3′end of p18 (nts 17269-17292 of CTV T36 clone) (F.P.) C-2052 CAC GGC TCT GTC 51 3′end of p23 (nts GTG ATC GCC CTA 19,000-19,020) with AGT CAC GCT AAA extension into the 3′end CAA AGT GAC of GLRaV-2 CPm coding sequence (nts 9454- 9474 Genbank Accession # DQ286725) (R.P.) C-2053 GTC ACT TTG TTT 52 BYV 3′end of CPm and AGC GTG ACT TAG the intergenic region of TTC GAC CTC GGT CP (nts 13547-13567 CGT CTT AGT Genbank Accession AF190581) with extension into 3′end of p18 (nts 17269-17292 of CTV T36 clone) (F.P.) C-2054 ACT AAG ACG ACC 53 3′end of p18 (nts 1729- GAG GTC GAA CTA 17292 of T36 CTV AGT CAC GCT AAA clone) with extension CAA AGT GAC into BYV 3′end of CPm and the intergenic region of CP (nts 13547-13667 Genbank Accession # AF190581) (R.P.) C-2055 CAC AAC GTC TAT 54 3′end of p13 ORF (nts ATC ATG GCC TAG 17581-17601 of CTV GTT TCA GAA ATT T36 clone) with GTC GAA TCG extension into the 3′end of EYFP-YN (AA 147- 154) from pFlag-CMV2 carrying bJun-YN (Hu et al., 2002) C-2056 CGA TTC GAC AAT 55 3′end of EYFP-YN (AA TTC TGA AAC CTA 147-154) from pFlag- GGC CAT GAT ATA CMV2 carrying bJun-YN GAC GTT GTG (Hu et al., 2002) with extension into the 3′end of p13 (nts 17581-17601 of CTV T36 clone) C-2057 GGC ATG GAC GAG 56 3′end EYFP-YC (AA CTG TAC AAGTAA 231-238) (Hu et al., TTG AAGTGG ACG 2002) with extension into GAATAA GTT 5′end of 3′NTR (nts 19021-19041 of CTV T36 clone) C-2058 AAC TTA TTC CGT 57 5′end of 3′NTR (nts CCA CTT CAA TTA 19021-19041 of CTV CTT GTA CAG CTC T36 clone) with GTC CAT GCC extension into 3′end EYFP-YC (AA 231-238) (Hu et al., 2002) C-2059 TCG CTC TTA CCT 58 BYSV CP 5′IR (nts TGC GAT AAC TAG 8516-8536 Genbank CAG CTT GCT TCT Accession # U51931) ACCTGA CAC with extension into the 3′end of p13 (nts 17,662-17,685 of CTV T36 clone) (F.P.) C-2063 GTA ACCTAG AGC 59 5′end of GUS ORF (nts GAA GTG CAA TCA 1-21) with extension into ATG TTA CGT CCT the 3′ end of BYSV CP GTA GAA ACC IR (with extension into the 3′end of BYSV CP IR (nts 8593-8616 Genbank Accession # U51931) (F.P.) C-2064 GGT TTC TAC AGG 60 3′end of BYSV CP IR ACG TAA CAT TGA (nts 8591-8618 Genbank TTG CACTTC GCT Accession # U51931) CTA GGTTAC AA with extension into the 5′ end of GUS ORF (nts 1- 21) (R.P) C-2067 CCG CAG CAG GGA 61 3′end of p13 (nts 17581- GGC AAA CAA TGA 17601 of CTV T36 GTT TCA GAA ATT clone) with extension GTC GAATCG into the 3′end of GUS (nts 1789-1812) (F.P.) C-2068 CGA TTC GAC AAT 62 3′end of GUS (nts 1789- TTC TGA AAC TCA 1812) with extension into TTG TTT GCCTCC the 3′end of p13 (nts CTG CTG CGG 17581-17601 of CTV T36 clone) C-2069 GTG TCA GGT AGA 63 3′end of p13 (nts 17662- AGC AAG CTG CTA 17685 of CTV T36 GTT ATC GCA AGG clone) with extension TAA GAG CGA into 5′end of BYSV IR CP 5′IR (nts 8516-8536 Genbank Accession # U51931) (R.P.) C-2070 ATG GAT GAG CTC 64 5′IR of p20 (nts 17686- TAC AAATGA AGT 17709 of CTV T36 CTA CTC AGT AGT clone) with extension ACG TCT ATT into the 3′end of GFP (nts 700-720) (F.P.) C-2071 AAT AGA CGT ACT 66 3′end of GFP (nts 700- ACT GAGTAG ACT 720) with extension into TCA TTT GTA GAG the 5′IR of p20 (nts CTC ATC CAT 17686-17709 of CTV T36 clone) (R.P.) C-2085 GCG G ATGCAT 66 3′end of p18 (nts 17201- TATTT GGTTTT ACA 17245 of CTV T36 ACA ACG GTA CGT clone) with two point TTC AAA ATG mutations (C-A(17205) and G-T(17210)) creating NstI site to replace the PstI site (F.P.) C-2087 AAG ACC TAT AAC 20 5′ end of TEV HC-Pro GTA GGT GGC ATG protease motif (nts AAG GCT CAA TAT 1959-1979 Genbank TCG GAT CTA Accession # M11458) with extension into the HC-Pro recognition sequence (nts 2415- 2438 genetic code sequence redundancy was used to eliminate duplication Genbank Accession # M11458 (F.P.) C-2088 ATG AAA ACT TAC 67 5′end of GFP ORF (nt AAT GTT GGA GGG 4-21) with extension into ATG GCT AGC AAA the TEV HC-Pro GGA GAA GAA recognition sequence (nts 2412-2433 Genbank Accession # M11458) (F.P.) C-2089 TTC TTC TCC TTT 68 TEV HC-Pro recognition GCT AGC CAT CCC sequence (nts 2412- TCC AAC ATT GTA 2438 Genbank AGT TTT CAT Accession # M11458) with extension into the 5′ end of GFP ORF sequence (nts 4-21) (R.P.) C-2091 GAG AAT CTT TAT 69 5′ end of TEV NIa TTT CAG AGT AAG protease motif (nts GGA CCA CGT GAT 6270-6291 Genbank Accession # M11458) with extension into its recognition sequence (nts 8499-8519 Genbank Accession # M11458) (F.P.) C-2092 GAA AAC CTA 70 5′end of GFP ORF (nts TACTTC CAATCG 1-23) with extension ATG GCT AGC AAA into the TEV-NIa GGA GAA GAA CT protease recognition sequence (nts 8499- 8519 genetic code sequence redundancy used to eliminate duplication Genbank Accession # M11458) (F.P.) C-2093 AGT TCT TCT CCT 71 TEV NIa protease TTG CTA GC CAT recognition sequence CGA TTG GAA GTA (nts 8499-8519 genetic TAG GTT TTC code sequence redundancy used to eliminate duplication Genbank Accession # M11458) with extension into the GFP ORF sequence (nts 1-23) (R.P.) C-2094 AAG ACCTAT AAC 72 5′ end of TEV-NIa GTA GGT GGC ATG protease motif sequence AAG GGA CCA CGT nts 6270-6291 Genbank GAT TAC AAC Accession # M11458) with extension into the HC-Pro recognition sequence (nts 2415- 2438 genetic code sequence redundancy used to eliminate duplication Genbank Accession # M11458) (F.P.) C-2095 CCC TCC AAC ATT 73 3′end of TEV NIa GTA AGT TTT CAT protease motif (nts 6959- TTG CGA GTA CAC 6981 Genbank CAATTC ACT accession # DQ986288) with extension into the TEV HC-Pro protease motif (nts 2415-2438 Genbank accession # M11453) (R.P.) C-2096 GAG ATT CTT TAT 74 5′end of TEV HC-Pro TTT CAG AGT AAG protease motif (nts GCT CAATAT TCG  1959-1979 Genbank GAT CTA AAG Accession # M11458) with extension into the TEV NIa protease recognition sequence (nts 8499-8519 Genbank accession # M11458) (F.P.) C-2097 CGA TTG GAA 75 3′end of HC-Pro GTATAG GTT TCC protease motif (nts TTC GGATTC CAA 2388-2411 Genbank ACCTGA ATG AAC accession # M11458) with extension into the TEV NIa protease recognition sequence (nts 8499-8519 Genbank accession # M11458) (R.P.) C-2098 GCC ACCTAC GTT 76 33′end of p23 (nts 18997- ATA GGT CTT CAT 19017 of CTV T36 GAT GAA GTG clone) with extension GTGTTC ACG GAG into the 5′end of TEV HC-Pro protease recognition sequence nts 2412-2435 (genetic code sequence redundancy used to eliminate duplication) Genbank Accession # M11458)(R.P.) C-2099 ACT CTG AAA ATA 77 3′end of p23 (nts 18994- AAG ATT CTC GAT 19017 of CTV T36 GAA GTG GTGTTC clone) with extension ACG GAG AAC into the 5′end of TEV NIa protease recognition sequence (nts 8499- 8519 Genbank Accession # M11458) (R.P.) M-804 CAT TTA CGA ACG 78 5′end of GFP (nts 1-20) ATA GCC ATG GCT with 3′end of TEV 5′NTR AGC AAA GGA GAA (nts 126-143 Genbank GAA Accession # M11458) (F.P.)

Polymerase Chain Reaction (PCR)

PCR was performed using diluted plasmids (1:50) as templates using Vent DNA polymerase (New England Biolabs, Ipswich, Ma.) according to the manufacturer recommendations.

Agro-Injection/Infiltration

Agro-inoculation of Nicotiana benthamiana was performed according to the procedure developed by Gowda et al., (2005) with minor modifications. Agrobacterium tumefaciens EHA 105 was transformed with the binary plasmid containing CTV, variants (expression vectors) and silencing suppressors (p19 of Tomato bushy stunt virus (Gowda et al., 2005); p24 of GLRaV-2 (Chiba et al., 2007), P1/HC-Pro of Turnip mosaic virus (Kasschau et al., 2003) and p22 of Tomato chlorosis virus (Cañizares et al., 2008) by heat shock method (37° C. for 5 minutes) and subsequently were grown at 28° C. for 48 hours (hrs) on luria burtani (LB) (Sigma-Aldrich, St Louis, Mo.) plates supplemented with antibiotics (kanamycin (50 microgram (μg)/milliliter (ml)) and Rifampicilin ((50 μg/ml)). The colonies (two individual colonies per construct) were grown overnight as seed cultures in LB medium supplemented with antibiotics. On the next day 0.5 ml of the seed culture was used to inoculate 35 ml of LB medium supplemented with antibiotics for overnight growth. The bacterial culture was centrifuged at 6,000 rotation per minute (rpm) and resuspended in 10 milli molar (mM) MgCL₂ and 10 mM MES. The pellet was washed with 10 mM MgCL₂ and 10 mM MES and suspended in induction medium; 10 mM MgCL₂ and 10 mM MES containing acetosyringone at a final concentration of 150 μM. The suspension was incubated in the induction medium for at least 5 hrs before injection into the stem or infiltration into the abaxial (lower) surface of N. benthamiana leaves.

Plant Growth Conditions

N. benthmaiana plants maintained in a growth-room (21° C. with 16 hrs of light in a 24 hr period) were used for agro-injection/agro-infiltration four weeks after transplanting.

Infection of Citrus Plants

Recombinant virions of CTV for infection of citrus plants were obtained from infiltrated and/or systemic leaves of N. benthamiana. The virions were partially purified and enriched by concentration over a sucrose cushion in a TL 100 or SW41 rotor (Robertson et al., 2005). Virions of constructs expressing two foreign proteins were concentrated two times over a step gradient followed by a cushion gradient in SW28 and SW41 rotors, respectively (Garnsey and Henderson, 1982). Inoculation of citrus plants was carried out by bark flap inoculation into 1-1.5 year old Citrus macrophylla seedlings (Robertson et al., 2005) which were grown in a greenhouse with temperatures ranging between approximately 25-32° C.

Protoplast Preparation, Transfection, RNA Isolation and Northern Blot Analysis

N. benthamiana leaf mesopyhll protoplasts were prepared according to the procedure previously developed by Nava-Castillo et al., (1997). Surface sterilized leaves from three week old N. benthamiana plants were gently slashed on the lower side with a sterile blade and incubated overnight in the dark (16-20 hrs) in 0.7M MMC (0.7M mannitol, 5 mM MES, 10 mM CaCl₂) supplemented with the 1% cellulose (Yakult Honsh, Tokyo, Japan) and 0.5% macerase pectinase enzymes (Calbiochem, La Jolla, Calif.).

Capped in vitro RNA transcripts from NotI or StuI linearized plasmid DNA were generated (Satyanarayana et al., 1999) using Sp6 RNA polymerase (Epicentre Technologies, WI) and were transfected into the protoplasts using PEG (poly ethylene glycol) as described by Satyanarayana et al., (1999). Four days after transfection, protoplasts were used for preparation of total RNA for northern blot hybridization analysis and isolation of virions. Protoplasts were pelleted in equal amounts in two 1.5 ml eppendorf tubes. The first tube was flash frozen in liquid nitrogen and stored at −80° C. for isolation of virions to subsequently inoculate a new batch of protoplasts to amplify virions (Satyanarayana et al., 2000). The second tube was used for RNA isolation by the buffard buffer disruption of protoplasts followed by phenol:chloroform:isoamyl alcohol (25:24:1) extraction and ethanol precipitation as previously described by Navas-Castillo et al., (1997) and Robertson et al., (2005). Total RNA was resuspended in 20 μl DNAse/RNAase free water and used in Northern blot hybridization analysis as previously described by Lewandowski and Dawson (1998). In brief, isolated RNA was heat denatured in denaturing buffer (8.6% formaldehyde, 67% formamide in 1×MOPS (5 mM sodium acetate, 1 mM EDTA, 0.02M MOPS pH=7.0) separated in a 0.9% agarose gel in 1×MOPS containing 1.9% formaldehyde, and transferred onto a nylon membrane (Boehringer Mannheim, Germany) by electroblotting. Pre-hybridization (at least 1 hr) and hybridization (overnight) were carried out in a hybridization oven (Sigma-Aldrich, St. Louis, Mo.) at 68° C. A 900 nts digoxigenin labeled RNA probe corresponding to the 3′ end of the CTV genome (plus strand specific CTV RNA probe) (Satyanarayana et al., 1999) was used for hybridization except when the insertion of the foreign genetic material was behind p23 in which case a digoxigenin labeled RNA probe was produced from PCR amplified DNA (reverse primer contain 3′NTR of CTV and SP6 phage promoter (C-1982) according to the manufacturer recommendation (Boehringer Mannheim, Germany) that is complimentary to the sequence inserted behind p23 in addition to the 3′NTR sequence of CTV.

Western Blots

After powdering the plant tissue in liquid nitrogen via grinding in a mortar and pestle, laemmli buffer (50 mM Tris-C1, pH 6.8, 2.5% 2-mercaptoethanol, 2% SDS, 0.1% bromophenol blue, 10% glycerol) was added (100 μl per 100 mg tissue). The sample was transferred to a 1.5 ml centrifuge tube and boiled in a water bath for 3 minutes followed by centrifugation at maximum speed for 2 minutes. The supernatant was transferred to a new tube and stored at −20° C. until further use. The electrophoresis was carried out in a 12% SDS-Polyacrylamide gel (Bio-Rad, Hercules, Calif.) followed by two hours of semi-dry blotting to transfer the protein onto a nitrocellulose membrane (Bio-Rad, Hercules, Calif.). The membrane was blocked for 1 hr at room temperature followed by incubation with the primary antibody of either CP (1:5000), GFP (1:100) (Clontech Laboratories, Palo Alto, Calif.) or GUS (1:1000) (Molecular probes, Eugene, Or.) for an hour followed incubation for 1 hr in horseradish peroxidase conjugated donkey anti-rabbit secondary antibody (1:10,000) (Amersham, Buckinghamshire, United Kingdom). Finally, the chemiluminescent system for western blot (Amersham, Buckinghamshire, United Kingdom) development on an X-ray film (Kodak, Rochester, N.Y.) was used according to the manufacturer recommendations.

Plant and Protoplast Photos

Plant pictures under UV or white light were taken with a Canon Camera (Canon EOS Digital Rebel XTi 400D, Lake Success, New York). Close up fluorescent pictures of plant parts or protoplast were taken using a fluorescent dissecting microscope (Zeiss Stemi SV 11 UV-fluorescence dissecting microscope, Carl Zeiss Jena, GmbH., Jena, Germany). High resolution protoplast pictures were taken using a confocal scanning microscope (Leica TCS SL, Leica Microsystems, Inc., Exton, Pa.).

Enzyme Linked Immunosorbent Assay (ELISA)

Double antibody sandwiched ELISA was used according to the procedure developed by Garnsey and Cambra (1991). A rabbit polyclonal antibody (1 μg/ml) was used for coating the ELISA plate. The plant tissue sample was diluted at a 1:20 in PBS-T (phosphate buffer saline-1% Tween 20) extraction buffer. The detection antibody used was Mab ECTV 172 (1:100K dilution).

GUS Assay

Citrus bark pieces or systemic leaves from Agro-inoculated N. benthamiana plants that were surface sterilized in alcohol (70% ethanol) followed by Sodium hypo chloride (10% solution) and washing three times in sterile distilled water before staining for GUS. The samples were incubated overnight in an EDTA-phosphate buffer (0.1M Na₂HPO₄, 1 mM Na₂EDTA) containing 1 mg/ml X-gluc (cyclohexylammounium salt: Gold Biotechnology, St Louis, Mo.). Fixing of the tissue was done in 95% ethanol:glacial acetic acid solution (3:1.

Example 1: Systems Used to Examine CTV-Based Expression Vectors

CTV-based expression vectors were examined in three systems, N. benthamiana mesophyll protoplasts as well as whole plants of N. benthaminia and Citrus macropylla. The full-length cDNA clone of CTV (pCTV9R) and a mutant with most of the p33 gene deleted (pCTV9RΔp33), which has a PstI restriction site removed making cloning easier and still retaining the ability to infect most citrus varieties (Tatineni et al., 2008), was used for building constructs to infect whole plants. Relatively quick assays were done in N. benthamiana protoplasts, which require constructs to be built in the SP6 transcription plasmid (Satyanarayana et al., 1999). A mini-replicon pCTVΔCla 333R (Gowda et al., 2001), with most of the 3′ genes removed, was convenient to use in protoplasts. The ultimate goal to obtain citrus trees infected with the different CTV expression vectors was much more difficult and time consuming. So far, agro-inoculate citrus trees has proven difficult. Thus, to avoid this difficulty virions are amplified and concentrated for inoculation of citrus trees by stem-slashing or bark-flap inoculation (Robertson et al., 2005; Satyanarayana et al., 2001). N. benthamiana protoplasts can be inoculated with in vitro produced transcripts of recombinant CTV constructs and the virus amplified by successively passaging virions in crude sap through a series of protoplasts (Folimonov et al., 2007; Satyanarayana et al., 2001; Tatineni et al., 2008). Also, recombinant CTV can be amplified in N. benthamiana plants after agro-inoculation (Gowda et al., 2005). The virus can infect mesophyll cells of agro-inoculated areas of leaves, but as the virus moves systemically into upper non-inoculated leaves, it is limited to vascular tissues and usually induces vein clearing and later vein necrosis. All of the vector constructs were examined during systemic infection of N. benthamiana plants. Since CTV virions do not resuspend after centrifugation to a pellet, virions have to be concentrated by centrifugation through a sucrose step gradient (Garnsey et al., 1977; Robertson et al., 2005). After inoculation, the tops of citrus plants were removed, and viral systemic infections were monitored in new growth after 2-3 months. Once trees were infected, inoculum (buds, leaf pieces, or shoots) from the first infected plants was then used to propagate new plants for experimentation. The whole process takes approximately one year. For this reason, the inventors chose to examine only the most promising vector constructs in citrus trees. Some of the later developed constructs are not yet in citrus.

Example 2: Addition of an Extra Gene at Different Locations within the CTV Genome

Insertions at the p13 Gene Site

The effective CTV vector developed previously (Folimonov et al., 2007) has the additional gene inserted between the two coat protein genes, positioning the foreign gene as the sixth gene from the 3′ terminus. Yet, the most highly expressed genes of CTV tend to be closer to the 3′ terminus. Thus, it appeared that positioning an inserted gene closer to the 3′ terminus could result in higher levels of expression. P13, the third gene from the 3′ terminus, is a relatively highly expressed gene that is not necessary for the infection of most of the CTV host range (Tatineni et al., 2008; Tatineni et al., in preparation). Yet, replacement of the p13 ORF with the GFP ORF was not successful in previous attempts (Folimonov et al., 2007). There were possible reasons for the failure. The previous construct was designed with the assumption that translation initiated at the first start codon, but the p13 ORF has a second in-frame AUG. Translation might normally start at the second AUG. However, fusion of the GFP ORF behind the second in frame AUG also did not express the reporter gene (Gowda et al., unpublished result). A second possibility is that the p13 controller element (CE) might extend into the p13 ORF or that ribosome recruitment is directed from within the ORF. Here, the inventors deleted the p13 CE and ORF and inserted a new ORF behind a heterologous CE in the p13 position. The GFP ORF controlled by the CP-CE from BYSV (101 nts from 8516-8616 accession # U51931), GLRaV-2 (198 nts from 9454-9651 accession # DQ286725) or BYV were engineered into pCTV9RΔp33 as a replacement for nts 17293-17581 (CTV33-Δ13-BY-GFP-57, CTV33-Δ13-G-GFP-65, CTV33-Δ13-B-GFP-66 respectively) (FIG. 1 A). RNA transcripts were used to inoculate a series of protoplasts to determine whether the constructs could replicate and whether virions formed sufficiently for passage in crude sap to a new batch of protoplasts. The fluorescence of infected protoplasts (data not presented) and northern blot hybridization analysis demonstrated the successive passage of the expression vectors through the protoplast transfers (FIG. 1B). Furthermore, the level of the GFP mRNA was similar to that of CP. Vectors sequences CTV33-Δ13-BY-GFP-57, CTV33-Δ13-G-GFP-65 and CTV33-Δ13-B-GFP-66 then were transferred into the Agrobacterium binary plasmid for agro-inoculation of N. benthamiana plants. All three vectors infected and moved systemically in vascular tissue of the N. benthamiana plants as indicated by fluorescence in leaves, buds, flowers and corolla (FIG. 1C), vein clearing phenotype in early stages, as well as confirmed by ELISA (Data not presented).

CTV33-Δ13-G-GFP-65 and CTV33-Δ13-B-GFP-66 were amplified and used to inoculate Citrus macrophylla plants. The initially infected plants exhibited bright fluorescence in vascular tissue (FIG. 1D). Fluorescence continued in these plants 2 years after inoculation.

The GFP ORF (720 nts) was replaced with the GUS ORF (1812 nts) in the same position to examine the expression of a larger foreign gene. The BYSV CP-CE was selected to drive the GUS ORF in expression vector CTV33-Δ13-BY-GUS-61 (FIG. 2A). RNA transcripts of this construct were transfected into protoplast where the virus replicated and passaged efficiently from one protoplast batch to another as indicated by northern blot hybridization analysis (FIG. 2B). In addition, it revealed that the level of accumulation of GUS mRNA was identical to the CP mRNA, and the CP and CPm mRNAs of vector were similar to that of the wild type virus. Agro-inoculation of N. benthamiana plants revealed that the construct infected and spread throughout the vascular tissue of the plants based on GUS staining and confirmed by ELISA (Data not presented) and the vein clearing phenotype.

Virions isolated from infiltrated leaves of N. benthamiana plants of CTV33-Δ13-BY-GUS-61 infected Citrus macrophylla plants as confirmed by ELISA (Data not presented) and the bioactivity of the GUS protein (FIG. 2C). The GUS gene was still biologically active in citrus 1.5 year after inoculation.

Technically, the above constructs replaced a gene (p13) rather than added an extra gene. To examine a vector with an extra gene between p13 and p20, the CP-CE of BYSV controlling the GFP ORF was inserted between nts 17685-17686 to yield CTV33-13-BY-GFP-69 (FIG. 3A). This vector should produce an extra subgenomic RNA between the subgenomic RNAs of p13 and p20. Vector CTV33-13-BY-GFP-69 was examined in N. benthamiana protoplasts and plants. In the protoplast system, CTV33-13-BY-GFP-69 replicated efficiently and was successfully passaged from one protoplast batch to another demonstrating efficient replication and virion formation as indicated by fluorescence (Data not presented) and northern blot hybridization analysis (FIG. 3B). The foreign mRNA accumulated at a relatively high level but the CP mRNA was reduced. Similar to the replacement of p13 constructs, agro-inoculation of the expression vector CTV33-13-BY-GFP-69 into N. benthamiana plants enabled the new vector to infect and spread throughout the vascular tissue (FIG. 3C).

Construct CTV33-13-BY-GFP-69 infected C. macrophylla plants as indicated by strong fluorescence throughout the vascular tissue (FIG. 3C) and confirmed by ELISA (Data not presented). The plants were still fluorescencing 2 years after inoculation.

Insertion Between p20 and p23

To examine expression of a foreign gene closer to the 3′ NTR of CTV, an extra gene was inserted between the p20 and p23 genes (nts 18312-18313). The BYV or BYSV CP-CE was used to drive the GFP mRNA in two vectors based on T36 CTV9RΔp33 (CTV33-20-B-GFP-49 and CTV33-20-BY-GFP-58) (FIG. 3-4A). The new vectors produced an extra sgRNA mRNA between the p20 and p23 sgRNAs (FIG. 4B). However, the accumulation of the p20 sg mRNA was substantially reduced. Both vectors replicated and were passaged in protoplasts, but the protoplast passage was reduced as demonstrated by reduced numbers of cells with GFP fluorescence and northern blot hybridization (FIGS. 4B & C). When both CTV33-20-B-GFP-49 or CTV33-20-BY-GFP-58 vectors were infiltrated into N. benthamiana leaves for transient expression, the vectors replicated and produced abundant amounts of GFP as indicated by fluorescence (Data not presented) and western blot analysis (FIG. 4D). However, when agro-inoculated into N. benthamiana plants, the constructs replicated but movement into upper non-inoculated leaves was random and often unsuccessful. Since systemic infection of N. benthamiana plants was marginal, no attempt was made to inoculate citrus.

Insertion Between p23 and 3′NTR

The next position to be examined was to make the inserted gene the 3′-most gene. Since CTV gene expression tends to be highest for genes positions nearer the 3′ terminus, this position could be expected to result in the highest level of expression of a foreign gene (Navas-Castillo et al., 1997; Hilf et al., 1995). Although the 3′ NTR has been analyzed (Satyanarayana et al., 2002a), it was not known what effect an extra gene in this area would have on the efficiency of replication. The insertion of an extra gene between the CP gene and the 3′NTR in Tobacco mosaic virus (TMV) and Alfalfa mosaic virus (AMV) failed to produce viable vectors (Dawson et al., 1989; Sánchez-Navarro et al., 2001). The CP-CE of BYSV, GLRaV-2 or BYV in front of the GFP ORF was inserted between nucleotides 19020 and 19021 creating vectors CTV33-23-BY-GFP-37, CTV33-23-G-GFP-40 and CTV33-23-B-GFP-42, respectively (FIG. 5A). All of the constructs when transfected into the protoplast replicated and were passaged efficiently as indicated by northern blot hybridization analysis (FIG. 5B) and GFP fluorescence (Data not presented). The GFP mRNA was the highest accumulating mRNA, with only slight decreases to the other mRNAs compared to that of the wild type virus (FIG. 5B). Furthermore, the constructs with a GFP insertion 3′ of the p23 ORF had the highest accumulation of the foreign gene mRNA among the constructs examined. CTV33-23-BY-GFP-37, CTV33-23-G-GFP-40 and CTV33-23-B-GFP-42 constructs were agro-inoculated into N. benthamiana plants. The infections spread systemically throughout the vascular tissue as demonstrated by the fluorescence (FIG. 5C), phenotype (vein clearing followed by necrosis), and ELISA (Data not presented). The fluorescence in the vascular tissue of N. benthamiana plants was extremely bright and continued for the life of the infected plants (FIG. 5C)

Construct CTV33-23-BY-GFP-37 was amplified by passage through 12 protoplast sets before citrus inoculation. C macrophylla plants that were bark-flap inoculated with the concentrated virions became infected. The infection of citrus was confirmed by fluorescence of GFP (FIGS. 3-5D) and ELISA (Data not presented). Inoculation of citrus with constructs CTV33-23-G-GFP-40 was done via amplification in agro-inoculated N. benthamiana plants. The infection rate was in 1 of 4 C. macrophylla plants as indicated by fluorescence (FIG. 5D) and confirmed by ELISA (Data not presented). Similar to N. benthamiana, citrus plants expressed bright fluorescence in the vascular tissue 12 weeks after inoculation and were still fluorescing 2.5 years later (FIG. 5D).

To examine the ability of the vector to express a larger gene at this position, the GUS ORF behind the BYSV CP-CE was inserted 3′ of the p23 gene resulting in construct CTV33-23-BY-GUS-60 (FIG. 6A). The construct replicated in successfully transfected protoplasts. However, the accumulation levels of all the CTV subgenomic RNAs were decreased profoundly compared to the wild type virus as demonstrated by northern blot hybridization analysis (FIG. 6B). Also, the CTV33-23-BY-GUS-60 construct passaged poorly in protoplasts (Data not presented). Yet, after agro-inoculation of N. benthamiana plants, the vector replicated and moved systemically as demonstrated by the systemic symptoms (vein clearing followed by necrosis), ELISA (Data not presented) and GUS assays. The activity of GUS in the N. benthamiana plants was continuously produced in old and new leaves until the death of the plant (FIG. 7C). Similar to CTV33-Δ13-BY-GUS-61, the location between p23 and 3′NTR was able to accommodate moderately to long genes albeit with a differential effect on sg RNA levels of upstream genes (FIG. 5B & FIG. 6B)

Concentrated virions from Construct CTV33-23-GUS-60 were used to inoculate C. macropyhlla plants, which became infected as confirmed by ELISA (Data not presented) and activity of the GUS gene (FIG. 6C). Furthermore, GUS activity and western blot analysis revealed the presence of the GUS gene in citrus 1.3 years after inoculation (FIG. 6C, FIG. 19).

Example 3: Production of an Extra Polypeptide without Producing an Extra Subgenomic mRNA

Internal Ribosome Entry Site Strategy (IRES)

The Tobacco Etch Virus (TEV) IRES

The 5′NTR of TEV mediates cap independent translation of the viral mRNA. Studies on the 5′NTR of TEV demonstrate its ability to initiate translation at an internal ORF in a bi-cistronic mRNA (Gallie, 2001; Niepel and Gallie, 1999). The 5′NTR of TEV (nts 2-144 Genbank accession # DQ986288) was inserted into a CTV mini-replicon behind the p23 ORF (between nts 19020-19021) followed by the GFP ORF (CTVp333R-23-ITEV-GFP) (FIG. 7A) to examine whether a bicistronic subgenomic mRNA would work with this virus. Although northern blot hybridization analysis demonstrated that the mini-replicon replicated and produced abundant amounts of the bicistronic mRNA in transfected N. benthamiana protoplasts (FIG. 7C), GFP fluorescence was not observed, suggesting a lack of translation of the second ORF in the bicistronic mRNA. The inventors also examined the 5′NTR TEV IRES construct in full length CTV in N. benthamiana protoplasts and plants. Construct CTV33-23-ITEV-GFP-41 was passaged efficiently from protoplast to the next protoplast sets (FIG. 7B), indicating the good replication and formation of virions, but no fluorescing protoplasts were observed demonstrating that this IRES did not work well in CTV (data not presented). This construct infected and moved systemically in N. benthamiana plants based on the systemic symptoms of vein clearing followed by necrosis and ELISA (Data not presented), but no GFP fluorescence was observed under UV light (Data not presented).

Active ribosome complementary sequence (ARC) IRES

Insertion of an IRES consensus sequence obtained from analysis of host and viral mRNAs (the engineered 3×ARC-1 (86 nts) IRES (Akbergenov et al., 2004)) was next examined for activity in CTV. This IRES was fused behind the p23 ORF (nts 19020-19021) in both the CTV mini-replicon (CTVp333R-23-I3×ARC-GFP) and Δp33CTV9R (CTV33-23-I3×ARC-GFP-43) as described above (FIG. 7 A). However, after infection of protoplasts and plants, no GFP fluorescence was observed even though the virus replicated well in both (FIGS. 7B&C).

Poly-Peptide Fusion

P23, the highest expressed gene of CTV, is a multifunctional protein that is essential for citrus infection. P23 is a silencing suppressor and controls plus to minus RNA ratio in infected cells via an RNA binding domain constituted of positive charged amino acid residues and Zn finger domain present between amino acid 50-86 (Lopez et al., 2000; Satyanarayana et al., 2002b; Lu et al., 2004). In order to create a gene fusion the HC-Pro or NIa protease motifs of TEV were selected to be fused at the C-terminus of p23 (between nts 19017 and 19018) (FIG. 8). The protease recognition sequence of the HC-Pro and NIa was duplicated between p23 and the protease and between the protease and GFP creating vectors CTV33-23-HC-GFP-72 and CTV33-23-NIa-GFP-73, respectively (FIG. 8). The processing of the protease motif from p23 should release the p23 with 7 extra amino acids at its C-terminus in the case of HC-Pro and 6 amino acids in the case of NIa. The GFP protein should have two extra and one extra amino acid after being cleaved from HC-Pro and NIa, respectively. The recognition sequences were switched between HC-Pro and NIa creating vectors CTV33-23-HCØ-GFP-74 and CTV33-23-NIaØ-GFP-75 as controls that are unable to be cleaved (FIG. 8). All the polypeptide fusion vectors were created in CTV binary vectors for infection of plants because in protoplast it was shown that p23 fusion did not affect the ability to replicate and pass between protoplast sets (Tatineni and Dawson, unpublished result). In N. benthamiana infiltrated leaves, all constructs fluoresced similarly to each other and to the free GFP constructs behind p23 (FIG. 9A). Furthermore, western immune-blot analysis from infiltrated leaves indicated a near-perfect processing of the reporter gene from the polypeptide fusion (FIG. 10). The GFP protein did not localize to the nucleus unlike the fusion to p23 without a protease processing releasing the reporter gene. Upon agro-inoculation of plants, only constructs with the protease and its homologous processing sites were able to move systemically into upper non-inoculated leaves. The fluorescence in upper non-inoculated leaves was weaker than those for the expression vectors CTV33-23-BY-GFP-37, CTV33-23-G-GFP-40 and CTV33-23-B-GFP-42 carrying GFP under its own controller element (FIG. 9B). Furthermore, it was easier to visualize fluorescence on the abaxial rather than the adaxial leaf surface (FIG. 9C). Upon inoculation of citrus with construct CTV33-23-HC-GFP-72, one plant became positive with relatively low ELISA value compared to others (Data not presented). The reporter gene activity was not detected.

Example 4: Production of More than One Extra Foreign Protein from CTV Vectors

Use of Single Controller Elements to Express Multiple Proteins

In order to exploit the polypeptide strategy to express multiple genes driven by the same controller element in a CTV based vector, a fusion polypeptide was created consisting of GFP/Protease (Pro)/GUS. Two different protease motifs were used in the different constructs, HC-Pro and NIa, with their proteolytic motifs and recognition sequences separating GFP ORF from the GUS ORF (FIGS. 14A & 3-16) (Carrington and Dougherty, 1988; Carrington et al., 1989). Theoretically, in case the NIa was the protease motif in the fusion, six extra amino acids are coupled with the N-terminal protein (GFP) at its C-terminus whereas only one extra amino acid is added to the N-terminus of GUS. Similarly, where HC-Pro was the protease within the fusion poly-peptide, 7 extra amino acids are added to the C-terminus of GFP and two extra amino acids added to the N-terminus of GUS. The fusion genes ranged in size between 3127 and 3480 nts.

Replacement of p13 Gene

The two fusions of GFP/Pro/GUS described above were engineered into the p13 site of CTV in the agro-inoculation binary vector under the control of the BYSV CP-CE (CTV33-Δ13-BYGFP-HC-GUS-77 with HC-Pro protease motif and CTV33-Δ13-BYGFP-NIa-GUS-78 with NIa protease motif) (FIG. 11A). The constructs were agro-inoculated to N. benthamiana for monitoring the ability to systemically infect the plant and produce GUS and GFP. Both genes were produced based on their assays (FIG. 11B). Western immune-blot analysis indicated the efficient processing of the GFP protein from the polypeptide fusion (FIG. 10). The virus multiplied and spread to high titers in N. benthamiana plants as indicated by symptom development in the upper leaves (FIG. 11B) and ELISA. However, the level of GFP fluorescence was less than that of vectors CTV33-Δ13-BY-GFP-57, CTV33-Δ13-G-GFP-65 and CTV33-Δ13-B-GFP-66 expressing the GFP alone and spread more slowly into the upper non-inoculated leaves than those vectors (Data not presented). In N. benthamiana plants, overlapping fluorescence and enzymatic activity of GUS were demonstrated 7 months after the injection of the construct revealing their stability (FIG. 12).

Insertion Between p23 and 3′NTR

In an attempt to improve the expression level of GFP and GUS, the fusion polypeptide was moved closer to the 3′NTR. The fusion gene with either BYSV, GLRaV-2 or BYV CP-CE with the protease of HC-Pro was inserted between p23 and 3′NTR referred to as CTV33-23-BY-GFP-HC-GUS-51, CTV33-23-G-GFP-HC-GUS-53 and CTV33-23-BY-GFP-HC-GUS-55 whereas with the NIa protease constructs were named, CTV33-23-BY-GFP-NIa-GUS-52, CTV33-23-G-GFP-NIa-GUS-54 and CTV33-23-BY-GFP-NIa-GUS-56, respectively (FIG. 13). After N. benthamiana plants were agro-inoculated, all the constructs multiplied and spread into the upper non-inoculated leaves as indicated by GFP fluorescence (FIG. 14A) and GUS activity (FIG. 14A). Similar to constructs CTV33-Δ13-BYGFP-HC-GUS-77 and CTV33-Δ13-BYGFP-NIa-GUS-78, fluorescence overlapping with GUS enzymatic activity was demonstrated 7 months after injection indicating the stability of the fusion. However, C. macrophylla plants infected with construct CTV33-23-BY-GFP-HC-GUS-51 revealed only faint fluorescence and almost no GUS activity (FIG. 14B) and high ELISA values.

Example 5: Use of Multiple Promoters to Express Foreign Genes Simultaneously

Bimolecular Fluorescence Complementation (BiFC) in CTV.

For examination of the insertion of two CP-CE controlling different ORFs, the BiFC system, which produces visible fluorescence only when the two proteins accumulate in the same cell, was used. This system was developed using the bJun fused to N-terminus of EYFP (A.A. 1-154) (referred to as bJunN) and bFos ORF fused to C-terminus of EYFP (A.A. 155-238) (referred to as bFosC) (Hu et al., 2002).

Both proteins are transported to the nucleus where they directly interact enabling the EYFP protein to regain its wild type folding pattern and results in emission of fluorescence upon activation by a blue light source (Excitation wave length is 525 nm and emission wavelength is 575 nm) (Hu et al., 2002). One or both components of BiFC were introduced into the CTV mini-replicon 3′ of the p23 ORF (between nts #19020 and 19021 Genbank Accession # AY170468) referred to as CTVp333R-23-BYbJunN, CTVp333R-23-GbFosC and CTVp333R-23-BYbJunN-GbFosC (FIG. 15 A). Northern blot hybridization analysis demonstrates the successful transfection of all three constructs into N. benthamiana protoplast (FIG. 15B). The two transcription factors interacted in the plant cell as demonstrated by nuclear fluorescence observed only in protoplasts infected with CTVp333R-23-BYbJunN-GBFosC (FIG. 15C). It is worth noting that the size of the two inserted genes is approximately identical to that of the GUS ORF.

As a control for the BiFC experiments, the inventors also introduced the genes individually into Δp33CTV9R behind p23 creating vectors CTV33-23-BYbJunN-97 and CTV33-23-GbFosC-98 so that only one component would be produced (FIG. 16B). Neither construct exhibited fluorescence in the nucleus.

Expression of Multiple Foreign Genes Simultaneously at the Same Location

P13 Replacement.

Both genes were introduced into a Δp33CTV9R (Satyanarayana et al., 1999, 2000, 2003; Tatineni et al., 2008) as a replacement of the p13 gene (replacement of the nucleotides deleted between 17292 and 17581), resulting in CTV33-Δ13-BYbJunN-GbFosC-76 (FIG. 16A). Transfection of protoplasts with the RNA transcripts of CTV33-Δ13-BYbJunN-GbFosC-76 resulted in the nuclear fluorescence of infected protoplasts (Data not presented). Similarly, infiltrated leaves of N. benthamiana plants with full length CTV33-Δ13-BYbJunN-GbFosC-76 emitted nuclear fluorescence (FIG. 16B). On the contrary, infiltrated leaves with constructs CTV33-23-BYbJunN-97 and CTV33-23-GbFosC-98 did not show any nuclear fluorescence (Data not presented). Monitoring stem phloem and leaf veins of N. benthamiana plants infiltrated with CTV33-Δ13-BYbJunN-GbFosC-76 seven weeks after infiltration revealed fluorescence of the vascular tissue indicating the ability of this construct to systemically infect upper leaves of N. benthamiana (FIG. 16B).

Insertion Between p23 and 3′NTR.

The next step was to examine expression of the two genes when positioned closer to the 3′ terminus. The two gene components of the BiFC system were introduced into CTVΔp33 behind p23 (between nts #19020 and 19021), CTV33-23-BYbJunN-GbFosC-59 (FIG. 3-17A). Upon RNA transfection of construct CTV33-23-BYbJunN-GbFosC-59, nuclear flourescence of infected protoplast was observed under the fluorescent microscope. However, it was difficult to pass the new construct from one protoplast batch to another, similar to GUS and the GFP/Pro/GUS fusion genes inserted at the same location. Upon agro-infiltration of N. benthamiana plants with CTV33-23-BYbJun-GbFosC-59 in full length CTV, fluorescence was observed in infiltrated areas. Systemic symptoms similar to that expected for infection of N. benthamiana by CTV was extremely delayed. However, monitoring upper non-inoculated leaves and phloem tissue of the stem at seven weeks after agro-infiltration of leaves revealed fluorescence of nuclei of the vascular tissue, demonstrating systemic infection by the vector (FIG. 17C). These results confirmed by ELISA, indicate that the position between p23 and 3′NTR can accommodate two extra genes without affecting the ability of CTV to systemically invade the plants. Similar to both genes replacing p13 in construct CTV33-Δ13-BYbJunN-GbFosC-76 there was a delay in the time frame of colonizing the upper vascular tissues by construct CTV33-23-BYbJunN-GbFosC-59. Nuclear fluorescence of systemic stem phloem tissue indicates that CTV33-Δ13-BYbJunN-GbFosC-76 infected more cells than construct CTV33-23-BYbJunN-GbFosC-59 (FIG. 16B & FIG. 17C). This difference in the number of cells infected indicates the better ability of CTV33-Δ13-BYbJunN-GbFosC-76 to move in N. benthamiana as compared to CTV33-23-BYbJunN-GbFosC-59.

Example 6: Expression of Multiple Foreign Genes Simultaneously from Different Locations

To express multiple foreign genes from two different positions, the inventors elected to replace the p13 gene and insert a second gene behind p23. CTV33-Δ13-BYbJunN-23-GbFosC-67 (FIG. 17A) was created via replacement of the p13 gene with the BYSV CP-CE driving the bJunN ORF and the GLRaV-2 CP-CE controlling the bFosC ORF inserted between the p23 ORF and the 3′NTR. CTV33-Δ3-BYbJunN-23-GbFosC-67 was transfected into protoplasts and Northern blot analysis revealed the replication of the virus (FIG. 17B). However, accumulation of the p23 mRNA was greatly reduced. CTV33-Δ13-BYbJunN-23-GbFosC-67 was agro-inoculated into N. benthamiana. The infiltration into the leaves indicated nuclear fluorescence of infected cells (FIG. 17C) which were much fewer in number compared to constructs CTV33-Δ13-BYbJunN-GbFosC-76 and CTV33-23-BYbJunN-GbFosC-59. Isolation of virions from leaves and transfection of protoplast was carried out resulting in nuclear fluorescence of infected protoplast indicating the successful formation of biologically active virions. However, systemic infection was not achieved in N. benthamiana as indicated by the lack of nuclear fluorescence in the stem and upper non-inoculated leaves of N. benthamiana and confirmed by ELISA.

In order to further study simultaneous multiple gene expression from the different locations as above, CTV33-Δ13-BYGUS-23-GGFP-71 was engineered such that the GUS ORF under the control of the BYSV CP-CE replaced the p13 gene(nts 17292-17582) and the GFP ORF under the control of the GLRaV-2 CP-CE was inserted between the p23 and 3′NTR (nts 19020 and 19021) (FIG. 18A). RNA transcripts of CTV33-Δp13-BYGUS-23-GGFP-71 were transfected into N. benthamiana protoplasts and northern blot analysis indicated efficient replication of the construct in protoplasts (FIG. 18B). Leaf infiltration of N. benthamiana plants with construct CTV33-Δp13-BYGUS-23-GGFP-71 resulted in replication of the virus as indicated by visible fluorescence under a UV light and by GUS activity (Data not presented). The agro-inoculated plants began to exhibit GUS activity and fluorescence in the upper non-inoculated leaves 6 weeks after infiltration (FIG. 3-18C). The systemic infection of upper leaves was slightly slower than constructs with only GFP alone. Also, the phenotype of vein clearing followed by necrosis associated with CTV infection of N. benthamiana vascular tissue occurred later than that of single gene vectors. The level of fluorescence when observed UV light appeared to be slightly less than that of the single gene constructs. However, the GFP fluorescence was more in plants infected with construct CTV33-Δp13BYGUS-23GGFP-71, which was controlled by its own CE, compared to that of the fusion in constructs (CTV33-23-BY-GFP-HC-GUS-51, CTV33-23-BY-GFP-NIa-GUS-52, CTV33-23-G-GFP-HC-GUS-53, CTV33-23-G-GFP-NIa-GUS-54, CTV33-Δ13-BYGFP-HC-GUS-77 and CTV33-Δ13-BYGFP-NIa-GUS-78). The activity of both genes continued until the death of the N. benthamiana plants. Similarly, in citrus the expression of both genes were better than the same genes in constructs CTV33-Δ13-BYGFP-NIa-GUS-78 and CTV33-23-BY-GFP-HC-GUS-51.

Example 7: Level of Foreign Gene Expression of the Different Constructs in Citrus

It is difficult to directly compare foreign gene expression from the different vectors in citrus due to the differences in the times of infection, the ages of the tissue and the effects of the inserted foreign gene cassette on the replication of the virus. Yet, protein presence in citrus is the best measure of expression level. Thus, western blot analysis was used to compare the relative level of expression of the different GFP and GUS constructs in citrus to that of CP protein, a house keeping gene to determine the replication levels. Western blots using the GFP antibodies and the CP antibody revealed a trend which confirms the relative higher expression levels near the 3′ end of the genome and a lower expression level when the inserted gene is moved further away from the 3′ end with the exception for the insertion between p13 and p20 (FIG. 19A). In contrary, the GUS expression in citrus revealed a higher relative expression level as replacement of p13 rather than insertion behind p23 (FIG. 19B).

Example 8: Multiple Gene Vectors

Plasmid Construction:

Three and four gene vectors were developed by introducing different combination of gene cassettes into the CTV genome at different locations. Three of the vectors were developed in CTV9RΔp33 in the pCAMBIA 1380 background (CTV33-BGFP-BYGUS-GTMVCP-79, CTV33-BGFP-GbFosC-BYbJunN-81 and CTV33-Δ13-BGFP-BYbJunN-GbFosC-82). The other three gene vectors (CTV-BASL-BYPTA-CP7-119, CTV-BASL-BYP10-CP7-131, CTV-BASL-BYPTA-CP10-120 and CTV-BRFP-BYGFP-CTMVCP-117) and one four gene vector (CTVΔ13-BRFP-GbFosC-BYbJunN-CTMVCP-118) were developed by modifying CTV9R in the background of pCAMBIA1380 altered by replacing the hygromycin ORF with the p22 ORF of Tomato chlorosis virus. For the ease of cloning the PstI restriction site in p33 ORF in full length CTV9R was eliminated by introducing a silent mutation using overlap extension PCR using primers 1749 and 1750 in combination with primer C-1436 and C-253 followed by digestion of both the overlap PCR product and CTV9R with XmaI and PmeI. Most of the gene cassettes were introduced into their locations by overlap extension PCR using the primers listed in table 1. The only exception was the insertion of green fluorescent protein cycle 3 in between the CPm and CP gene. Introducing the GFPC3 gene cassette into that location was done by restriction digestion of 9-47RGFP plasmid and point mutated CTV9R in pCAMBIA1380 with PmeI and PstI.

Expression of Three and Four Foreign Genes Simultaneously

After successfully expressing two genes in N. benthamiana and citrus with one and two different controller elements we are building vectors to express three and four foreign genes from three and four different controller elements, respectively. The reporter genes used in different combinations were the green fluorescent protein (cycle 3 GFP, GFPC3), red fluorescent protein (tag red fluorescent protein, RFP), Bimolecular fluorescence complementation using the bFos and bJun mammalian transcription factors (Hu et al., 2002), β-glucuronidase (GUS) gene from Escherichia coli and the Tobacco mosaic virus (TMV) coat protein gene (CP). Similarly, three gene vectors were built in different combinations to express two antimicrobial peptides (AMPs) from Tachypleus tridentatus and Sus scorfa, Allium sativum lectin (ASL) and Pinellia ternata agglutinin (PTA). The three gene vectors were either expressed from two or three locations within the CTV genome

Expression of Three Foreign Genes from Three Different Locations Simultaneously:

Six vectors were built to express three foreign genes from three different locations. The vectors were built to express the genes either from CTV9RΔp33 or full length CTV9R.

Vectors Built to Express Three Genes from Three Different Locations in CTV9RΔp33

Two vectors were built by inserting the three extra gene cassettes into CTV9RΔp33 creating expression vectors CTV33-BGFP-BYGUS-GTMVCP-79 (FIG. 26) and CTV33-Δ13-BGFP-BYbJunN-GbFosC-82 (FIG. 28). CTV33-BGFP-BYGUS-GTMVCP-79 expresses the three ORFs of GFP (insertion between CPm and CP), GUS (insertion between p13 and p20) and the coat protein of TMV (insertion between p23 and 3′UTR) under the CP-CE of BYV, BYSV and GLRaV-2, respectively. CTV33-Δ13-BGFP-BYbJunN-GbFosC-82 expresses the three ORFs of GFP (insertion between CPm and CP), bJunN ORF (replacement of p13) and bFosC (insertion between p23 and 3′UTR) under the CP-CE of BYV, BYSV and GLRaV-2, respectively. The two vectors were infiltrated into N. benthamiana leaves in combination with silencing suppressors and inoculated into citrus using the procedure of Gowda et al., 2005. As leaves were cut and grinded to isolate virions over 70% sucrose cushion gradient just 5 days after infiltration into the N. benthamiana leaves it was not likely that these plants will get systemically infected, thus they were discarded. The fluorescence of infiltrated leaves under hand held UV indicated the expression of the GFP protein in both CTV33-BGFP-BYGUS-GTMVCP-79 and CTV33-Δ13-BGFP-BYbJunN-GbFosC-82 indicating the ability of the created vector to replicate in the N. benthamiana leaves. Electron microscope grids prepared from leaf dips of infiltrated N. benthamiana leaves for construct CTV33-BGFP-BYGUS-GTMVCP-79 and CTV33-Δ13-BGFP-BYbJunN-GbFosC-82 indicated the formation of virions a prerequisite for the successful mechanical inoculation of citrus seedlings with CTV. Furthermore, in the case of CTV33-BGFP-BYGUS-GTMVCP-79 and not CTV33-Δ13-BGFP-BYbJunN-GbFosC-82 there was the formation of rod-shaped structures referred to as TMV pseudo-virions a characteristic of the expression of the TMV coat protein.

Vectors Built to Express Three Genes from Three Different Locations in CTV9R

Four vectors were built to express three foreign genes from the same three different locations within the CTV genome. The three locations selected were insertion between CPm and CP, p13 and p20 and p23 and 3′UTR. For the ease of cloning into the full length CTV infectious clone a the PstI site within the p33 ORF was eliminated by introducing a silent point mutation by overlap extension PCR. Three of the four vectors were created by using different combinations of the two AMPs, ASL and PTA resulting in expression vectors CTV-BASL-BYPTA-CP7-119, CTV-BASL-BYP10-CP7-131 and CTV-BASL-BYPTA-CP10-120. The fourth vector named CTV-BRFP-BYGFP-CTMVCP-117 was created by inserting the ORFs of GFP, RFP and TMV CP under the control of BYV, BYSV and duplicated CP-CE of CTV. All the vectors were infiltrated into N. benthamiana to monitor the development of systemic infection. CTV-BASL-BYPTA-CP7-119 developed efficient systemic infection in 1 N. benthamiana plant. Plants infiltrated with vector CTV-BRFP-BYGFP-CTMVCP-117 revealed fluorescence in systemic leaves under hand held UV. Upon development of pronounced systemic infection, virions from CTV-BRFP-BYGFP-CTMVCP-117 will be concentrated over a sucrose step gradient and a sucrose cushion in order to inoculate citrus plants similar to the procedure recently followed for vector CTV-BASL-BYPTA-CP7-119

Expression of Three Foreign Genes from Two Different Locations Simultaneously:

Two vectors were created for the simultaneous expression of three genes from two different locations within the CTV genome. One vector was built in CTV9RΔp33 creating expression vector CTV33-BGFP-GbFosC-BYbJunN-81 whereas the other vector was built in full length CTV9R named CTVΔ13-GbFosC-BYbJunN-CTMVCP-129.

Vector Built to Express Three genes from Two different locations in CTV9RΔp33:

CTV33-BGFP-GbFosC-BYbJunN-81 (FIG. 27) was engineered through modifying CTV9RΔp33 by inserting a single gene cassette between CPm and CP (GFP ORF under the control of BYV CP-CE) and a double gene cassette (bFosC ORF followed by bJunN ORF under the control of GLRaV-2 and BYSV CP-CE, respectively) as an insertion between p23 and 3′UTR. A 1:1 mixture of 4 different silencing suppressors and CTV33-BGFP-GbFosC-BYbJunN-81 were infiltrated into N. benthamiana leaves. Electron microscopy from grids of leaf dips revealed the formation of virions similar to constructs CTV33-BGFP-BYGUS-GTMVCP-79 and CTV33-Δ13-BGFP-BYbJunN-GbFosC-82. In addition, the infiltrated leaves revealed strong fluorescence under hand held UV light. Infiltrated leaves were used to concentrate virions on a 70% sucrose cushion in an attempt to infect citrus seedlings.

Vector Built to Express Three genes from Two different locations in CTV9R:

CTV9R was modified by inserting a double gene cassette (bFosC ORF followed by bJunN ORF under the control of GLRaV-2 and BYSV CP-CE, respectively) as replacement of p13 and a gene cassette (TMV CP ORF under the control of the duplicated CP-CE) as an insertion between p23 and 3′UTR creating expression vector CTVΔ13-GbFosC-BYbJunN-CTMVCP-129 (FIG. 21). This vector is recently infiltrated into N. benthamiana leaves. After systemic infection of N. benthamiana the virions will be concentrated to enable the inoculation of citrus plants.

Expression of Four Foreign Genes from Three Different Locations Simultaneously:

In order to build the four gene vector we used four gene cassettes located at three different locations within the CTV genome. The RFP ORF was introduced between CPm and CP under the control of the BYV CP-CE, the two BiFC components bFosC and bJunN under the control of GLRaV-2 and BYSV respectively were introduced as a replacement of the p13 gene and the TMV ORF under the control of the duplicated CP-CE of CTV was introduced behind p23. The four gene vector named CTVΔ13-BRFP-GbFosC-BYbJunN-CTMVCP-118 was infiltrated into the N. benthamiana leaves for the development of systemic infection. Upon systemic infection virion concentration will be carried out over a sucrose step gradient and cushion for the infection of the citrus trees.

Discussion Related to Examples 1-8

In this work, CTV constructs that are extraordinarily permissive in allowing insertion of foreign sequences at different places in the 3′ portion of the genome are disclosed. Numerous different potential vector constructs to express foreign genes via additional subgenomic RNAs, di-cistronic mRNAs, or protease processing of fusion proteins were created and examined. Remarkably, most of these constructs functioned as vectors. Additionally, that the CTV constructs disclosed herein are capable of simultaneously producing large amounts of multiple foreign proteins or peptides.

The ultimate goal was to develop high expressing and stable vectors for the natural CTV host, citrus. Thus, virions were concentrated from N. benthamiana plants infected with 12 different constructs that spread and expressed moderate to high levels of the foreign protein(s) and used to inoculate citrus. C macrophylla plants became positive for infection between 6-60 weeks after inoculation depending on the insert length in the virus and the amount of virions concentrated from the N. benthamiana leaves that were used for inoculation. Most of the constructs that infected citrus produced moderate levels of the reporter gene/s.

Several approaches were examined for expression of foreign genes from CTV. The first approach was the “add-a-gene” strategy that involved the addition or duplication of a controller element and an additional ORF, which resulted in an additional subgenomic RNA. The “add-a-gene” approach was developed initially in TMV via duplicating the CP subgenomic promoter controlling a foreign gene (Dawson et al., 1989; Donson et al., 1991; Shivprasad et al., 1999). An advantage of this strategy is that it expresses the exact protein with no additional amino acids added to the N or/and C terminus which could affect its biological activity, at relatively high levels. However, there are limitations of this strategy that should be considered. Duplication of the controller element can lead to homologous recombination resulting in the loss of the gene of interest (Chapman et al., 1992; Dawson et al., 1989). Although this made the TMV insert unstable, it appeared to have little effect on the stability in CTV (Folimonov et al., 2007). The use of a heterologous controller element from related viruses stabilized the TMV insertions. However, heterologous controller elements usually are differentially recognized by the replicase complex of the virus (Folimonov et al., 2007; Shivprasad et al., 1999). This observation can be utilized to regulate the levels of desired gene expression (Shivprasad et al., 1999). An important consideration is that there can be competition between the different subgenomic RNAs of a virus. With TMV, the extra gene competed with the coat protein gene and the movement gene. There appeared to be a maximal capacity for production of subgenomic RNAs that was divided among the three RNAs. Manipulations that resulted in increases in one resulted in decreases in the others. One solution was to reduce coat protein production to allow optimal foreign gene and movement gene expression (Shivprasad et al., 1999; Girdishivelli et al., 2000). Yet, CTV subgenomic mRNAs appeared to be much less competitive (Folimonov et al., 2007; Ayllón et al., 2003).

In previous work, a CTV vector was created that expressed an extra gene between the CP and CPm genes that was an effective and stable vector in citrus trees. The foreign gene was in position 6 from the 3′ terminus (Folimonov et al., 2007). The position of the extra gene was chosen arbitrarily. Here the inventors continued vector design in an attempt to define the limits of manipulation of the CTV genome in producing extra proteins or peptides. The virus expresses its ten 3′ genes via sg mRNAs (Hilf et al., 1995). One rule of CTV gene expression is that genes nearer the 3′ terminus are transcribed higher than internal genes. For example, transcription of the p33 gene, which is at position 10 from the 3′ terminus, is very low in its native position, but transcription became very high when the p33 gene was moved near the 3′ terminus (Satyanarayana et al., 1999). Thus, expression of foreign genes from positions nearer the 3′ terminus might result in higher levels than from the position 6 arbitrarily chosen in the first vector (Folimonov et al., 2007). Yet, based on results from other viruses, only certain positions within the viral genome are likely to tolerate extra gene insertions. For example, with TMV or Alfalfa mosaic virus the location between CP and 3′NTR did not accommodate an insert (Dawson et al., 1989; Lehto and Dawson, 1990; Sanchez-Navarro et al., 2001). Remarkably, almost all of the constructs with insertions in CTV within the p13 deletion, between p13 and p20, and between p23 and the 3′ NTR were viable. In contrast, it was found that the only position the virus did not tolerate insertions was between the p20 and p23 genes. It is possible that these insertions interfered with the transcription of either of the adjacent genes.

Another strategy to express foreign genes in a viral vector consists of in-frame fusion of an ORF of interest to a viral ORF at either the N or C terminus. The two proteins can be released by engineering a protease and processing sites between the two proteins (Dolja et al., 1997; Gopinath et al., 2000). It was first adapted in the potyviridae, tobacco etch virus (Dolja et al., 1992). The major advantage of polyprotein fusion strategy is that the foreign protein is expressed in 1:1 ratio with the viral protein. A major limitation is that this process adds extra amino acids at the N and/or C termini of both proteins, which may affect their biological activities.

A series of constructs utilizing the HC-Pro or NIa proteases from potyviruses to enable post translational processing of the engineered polyprotein to release free GFP, protease, and the p23 protein were created. These vectors were able to systemically infect N. benthamiana. The systemic movement of these constructs was slower than the expression vector constructs containing only the GFP ORF as an extra gene. The slower systemic movement and the lower levels of GFP expression in the systemic leaves partially could be attributed to the extra C-terminal amino acids of p23 reduced its activity in RNA silencing suppression or amplification of viral RNAs or the protease processing delayed its activity. Although these constructs did not produce the maximal levels of foreign protein, they were viable vectors expressing substantial amounts of GFP.

Upon identifying the locations within the CTV genome that could accommodate foreign gene inserts, strategies were designed to construct viral vectors that express multiple genes. The first strategy depended on the use of a single controller element driving the transcription of a polypeptide gene. The fusion gene that consisted of GFP/Pro/GUS, ranged in size from 3127 nts to 3480 nts. Other strategies utilized two extra CEs to produce two extra sg RNAs simultaneously. This strategy gave the flexibility to insert the two genes in tandem in the same location or in two different locations. Both strategies worked.

Heterologous protein expression in whole plant is usually accomplished by development of transgenic plants by insertion of foreign DNA into the plastid or nuclear genome. Plastid transformation has been successful for only a few annual crops. Time and success of nuclear transformation varies among the different crops. Certain plants are more recalcitrant to transformation and subsequent regeneration than others. There are other disadvantages, particularly in perennial crops. For example, citrus has a long juvenile stage after regeneration that prolongs the time necessary to evaluate the horticultural characteristics and delays the time to commercial use. Another major disadvantage is that transformation is limited to the next generation of plants.

The inventors have now developed a series of different CTV vectors, each with different characteristics that are more effective under specific conditions. For example, with the “add-a-gene” vectors, the inventors would advocate the expression of a small gene in 3′ of the p23 gene in CTV for maximal expression. A medium gene could be more efficiently expressed from within the p13 area. A large gene probably would be better accommodated as an insertion between CP and CPm where it would disrupt the viral subgenomic RNAs less and result in better systemic invasion of the plant. For expression of smaller proteins, peptides, or RNAs to target RNA silencing, it is possible that the virus could accommodate 3 or 4 different genes. Different combinations of extra sg RNAs and protease processing can be chosen. Although two foreign proteins have been produced from other viruses, CTV is unique in usefulness because of its stability. The original vector has been continuously producing GFP for 8 years.

The uses of the CTV based expression vector have evolved since its inception. It was initially developed as a laboratory tool for citrus improvement. The vector was designed to express potential genes for transformation of citrus. Results of the effect of the heterologous gene in citrus, particularly if the effect was expected in mature tissue or fruit, could be obtained by the virus years before results would come from direct transformation. However, conditions and needs of the citrus industry have changed due to the invasion of a new bacterial disease referred to as Huanglongbing (HLB). This disease has spread so rapidly and is so damaging that the survival of the citrus industry is threatened. Initially, the CTV vector was used to identify antimicrobial peptides with activity against the HLB bacterium for transformation into citrus. However, the disease is spreading so rapidly that transgenic plants may not be available in time to save the industry. Due to the remarkable stability, the CTV vector now is being considered for use in the field to protect citrus trees and to treat infected trees until resistant transgenic plants become available. The CTV vector as a tool in the field to fight an invading disease of citrus is only one example of what viral vectors can do for agriculture. The possibilities are many for very stable vectors like those of CTV and perennial crops, particularly trees. Many trees are productive for 100 years or more. During the lifespan of the trees technologies changes and disease and pest pressures change. To improve trees by traditional transformation methods requires removing all of the present trees from the field and replanting. The use of a viral vector could add new genes to the existing trees.

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While various disclosed embodiments have been described above, it should be understood that they have been presented by way of example only, and not limitation. Numerous changes to the subject matter disclosed herein can be made in accordance with this Disclosure without departing from the spirit or scope of this Disclosure. In addition, while a particular feature may have been disclosed with respect to only one of several implementations, such feature may be combined with one or more other features of the other implementations as may be desired and advantageous for any given or particular application.

Thus, the breadth and scope of the subject matter provided in this Disclosure should not be limited by any of the above explicitly described embodiments. Rather, the scope of this Disclosure should be defined in accordance with the following claims and their equivalents.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting. As used herein, the singular forms “a,” “an,” and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise. Furthermore, to the extent that the terms “including,” “includes,” “having,” “has,” “with,” or variants thereof are used in either the detailed description and/or the claims, such terms are intended to be inclusive in a manner similar to the term “comprising.”

Unless otherwise defined, all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which embodiments belong. It will be further understood that terms, such as those defined in commonly used dictionaries, should be interpreted as having a meaning that is consistent with their meaning in the context of the relevant art and will not be interpreted in an idealized or overly formal sense unless expressly so defined herein.

The teachings of any patents, patent applications, technical or scientific articles or other references are incorporated herein in their entirety to the extent not inconsistent with the teachings herein. 

What is claimed is:
 1. A method of transfecting a citrus tree with a gene of interest having a 5′ end and a 3′ end, said method comprising inoculating said citrus tree with a sample comprising at least one Citrus tristeza virus (CTV) vector to produce an inoculated tree, said CTV vector engineered to comprise a construct comprising a heterologous gene of interest and a subgenomic RNA (sgRNA) heterologous controller element (CE) positioned upstream of the 5′ end of said heterologous gene of interest so as to control expression of said heterologous gene of interest; and growing said inoculated tree under conditions to allow a systemic infection of said tree with said at least one CTV vector; wherein expression of said heterologous gene of interest occurs for two months or more in the tree with a majority of virus in the systemic infection comprising said CTV vector. 